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Are immunoglobulin E levels associated with early wheezing? A prospective study in Brazilian infants

¹ Dept of Pediatrics and Center for Investigation in Pediatrics, ² Dept of Clinical Pathology, State University of Campinas (UNICAMP) Medical School, Campinas, Brazil

CORRESPONDENCE: J.D. Ribeiro, Center for Investigation in Pediatrics, State University of Campinas (UNICAMP) Medical School, P.O. Box 6111, 13083-070, Campinas-SP, Brazil. Fax: 55 1932898638. E-mail: dirceu@head.fcm.unicamp.br

Keywords: immunoglobulin E, infants, skin-prick test, wheezing

Received: February 27, 2001
Accepted March 3, 2002

	Abstract

TOP Abstract Material and methods Results Discussion Acknowledgements References

 
The relationship between wheezing or asthma and serum immunoglobulin (Ig)E levels in early life is unclear. The aim of this study was to follow-up the IgE immune response in infants that did, or did not, develop recurrent wheezing during their first year of life.

One-hundred and two randomised term neonates were included, in which IgE levels were quantified in cord blood samples, at 3, 6, 9 and 12 months of age. Specific IgE levels for food and inhalant allergens and the skin-prick test for inhalant allergens were also assessed at 6 and 12 months.

During clinical follow-up, 32 (31%) infants presented with two or more wheezing episodes, while 70 (69%) had no wheezing. Total IgE levels were significantly higher up to 12 months in wheezing infants when compared to nonwheezing group. At 12 months, the specific IgE levels to cow's milk, egg white and mites were higher in infants with recurrent wheezing. There was no influence of family history for atopy on IgE levels. The skin-prick tests were positive in 14% and 23% in wheezing infants at 6 and 12 months, respectively.

These results indicate an early allergic sensitisation in wheezing infants, suggesting an altered immunoregulatory T-cell role in immunoglobulin E production.

Recurrent wheezing in infancy is a heterogeneous condition. Some children have transient early wheezing, whereas in others, the respiratory symptoms occurring in early life may be the first manifestation of asthma 1.

Factors affecting wheezing in the early years of life and their relationship to the later development of asthma are currently under investigation. The possibility that immune mechanisms may contribute to the beginning of wheeze has been supported by studies that tend to favour an immunoglobulin (Ig)E-mediated hypersensitivity type of mechanism. Some authors suggested a prolonged activation of T-helper (Th)2-like immune response after bronchiolitis 2, 3. Other authors have found higher total IgE levels in young children that presented with persistent wheezing 4.

Little is known about the longitudinal relationship between the IgE immune responses and allergic sensitisation in infants with early wheezing. The aim of this study was to evaluate prospectively the development of the immune response mediated by IgE and its association with allergic sensitization in a group of infants that developed recurrent wheezing during their first year of life.

	Material and methods

TOP Abstract Material and methods Results Discussion Acknowledgements References

 
Patients
This is a 1-yr prospective study that enrolled healthy term neonates weighting >2,500 g. Term neonates (n=282) born from April 1996–May 1997 between 08:00–16:00 h, at the University Hospital were randomly included. Twenty-one cases were excluded because the neonates weighted <2,500 g. One-hundred and fifty cases were further excluded because the mothers did not give consent to join the study. Thus, 114 children (including three pairs of nonidentical twins) were included in the study.

Regarding the clinical manifestations of atopy, infants were followed up from birth to 12 months of age. During the clinical follow-up, these infants were classified as three groups: I) recurrent wheezing; II) other manifestations of atopy, such as urticaria, or reactions to insect stings; III) asymptomatic group 5. The children from group II were excluded since they presented no respiratory symptoms, and a total of 102 cases were analysed.

This study was approved by the Medical Ethics Committee of the University Hospital at the State University of Campinas Medical School (Brazil) and informed consent was provided by the parents before enrolling the child in the study.

Study design
All infants were examined by the same physician at 3, 6, 9, and 12 months of age at the University Hospital. The mothers answered a standardised questionnaire about clinical manifestations of their babies, including whether or not they presented with episodes of wheezing, the duration of breast-feeding and when egg white was offered to their infants.

Recurrent wheezing was defined as at least two episodes with good response to a ß-adrenergic agonist inhalation and no evidence of respiratory bacterial infection. The ß₂-agonist fenoterol in saline (0.9%) was administered by an oxygen nebuliser for 5–10 min. The effects of the ß₂-agonist were measured by clinical exam 15 and 30 min after the inhalation by a decrease in respiratory rate and the absence of wheezing at auscultation. A physician clinically documented the episodes of wheezing during the follow-up, and additional examinations were performed at other intervals when necessary.

A positive family history for atopy was considered whenever parents, siblings or grandparents had one or more atopic disorders (asthma, eczema, rhinitis, food allergy). Maternal atopy was confirmed by a positive skin-prick test or a high total IgE level (>180 international units (IU)·mL^–1) without helminthic infestation.

Cord blood samples were collected immediately after birth by using standard procedures, which included careful cleansing of the cord and strict puncture of the umbilical vein to avoid maternal contamination. A serum sample was obtained from the newborns and also at 3, 6, 9, 12 months of age for total IgE measurement. At 6 and 9 months, the specific IgE levels to cow's milk, egg white and mites (Dermatophagoides pteronyssinus and D. farinae) were determined. All samples were stored at –80°C until assayed. Furthermore, all infants were investigated for helminthic infestation at 6 and 12 months of age and those with a positive exam were excluded.

Allergy skin-prick test
The allergy skin-prick test was performed on infants at 6 and 12 months of age with standardised extracts from house dust and mites (D. pteronyssinus, D. farinae), obtained from Daught Laboratories® (Allergomed Division, Madrid, Spain). Additional skin-prick tests were performed in the mothers on standardised extracts from moulds, as well as dog and cat epithelia. The tests were done in the absence of antihistaminic treatment. Histamine (10 mg·mL^–1) was used as a positive control and diluent saline solution as a negative control. A positive test was considered if, after 15–20 min, half of the sum of the largest diameter and its perpendicular measured 3 mm.

Laboratory methods
Total IgE was measured using an ultrasensitive enzyme-linked immunoassay, IM_x total IgE assay (Abbott Laboratories®, Abbott Park, IL, USA), based on microparticle enzyme immunoassay. The results were expressed in IU·mL^–1 (1 IU·mL^–1=2.4 µg of IgE·L^–1). The minimum sensitivity of the assay was 0.048 IU·mL^–1.

Specific IgE was measured by immunochemiluminometric assay, using the Magic Lite System (Bayer Diagnostics®, Sudbury, UK). The results were expressed in standard units (SU·mL^–1) and they were classified into conventional allergy classes (0–5). The high sensitivity protocol was used, with a cut-off value of 0.5 SU·mL^–1. A positive test was considered when the values were >0.5 SU·mL^–1 (0–1 class).

Total serum IgA was measured by nephelometry (Beckman Instruments® Inc., Galway, Ireland) in cord blood samples. An IgA level 3.23 mg·dL^–1 was considered to represent contamination of the cord serum with maternal serum, and the sample was excluded 6.

Statistical methods
IgE geometric mean values and standard deviations (sd) were calculated by logarithmic transformation, since IgE values did not show a gaussian distribution. Analysis of variance (ANOVA) with repeated measures was used to analyse the IgE levels in wheezing and nonwheezing infants, and the influence of family history of atopy. The Generalised Estimation Equation evaluated the influence of family history for atopy on specific IgE levels. The correlation between specific IgE and total IgE levels was analysed using the Pearson correlation coefficient and the concordance with the skin-prick test by the Kappa coefficient. The Wilcoxon rank-sum test was employed to compare the specific IgE levels between wheezing and nonwheezing at 6 and 12 months of age. The Chi-squared test was used to compare the two groups in relation to the positive skin-prick test and specific IgE levels. All statistical analyses were considered significant when p-values were 0.05.

	Results

TOP Abstract Material and methods Results Discussion Acknowledgements References

 
One-hundred and two infants were included in this study. There were 54 (53%) males, 61 (60%) Whites and 41 (40%) Blacks. During the follow-up to 12 months of age, 32 (31%) presented with two or more wheezing episodes and 70 (69%) had no symptoms of wheeze or atopy. Three cord blood samples (3%) were excluded from the analyses because of maternal blood contamination. One sample at 6 months and two samples at 12 months were also excluded due to helminthic infection.

There were 48 infants (47%) that had been breast-fed for <6 months and their mothers started to offer them cow's milk at 3 months of age. Twelve infants (12%) received cow's milk since their birth. The egg white was given after 3 months of age to these infants.

Total and specific immunoglobulin E levels and presence of recurrent wheezing
Total serum IgE levels increased according to the age in both group of infants. Mean total IgE levels were higher (p<0.0004, ANOVA) in the recurrent wheezing group when compared to the nonwheezing group at all intervals (fig. 1).

View larger version (18K): [in this window] [in a new window]   Fig. 1.— Mean total immunoglobulin E (IgE) levels (log values) in infants with recurrent wheezing () and asymptomatic infants (•) during their first year of life. The vertical bars represent the standard deviation. For repeated measures analysis of variance, p=0.004.

View larger version (17K): [in this window] [in a new window]   Fig. 2.— Specific immunoglobulin E (IgE) levels to egg white and cow's milk in infants with recurrent wheezing (W; ) and asymptomatic infants (NW; ) at 12 months of age. The extreme values to egg white (W=89.14 SU·mL–1) and cow's milk (W=80.93 SU·mL–1) were not plotted. Mean: solid line; Median: dotted line. Wilcoxon rank-sum test for egg white: p<0.04; for cow's milk: p<0.02.

View larger version (16K): [in this window] [in a new window]   Fig. 3.— Specific immunoglobulin E (IgE) levels to mite in infants with recurrent wheezing (W; ) and asymptomatic infants (NW; ) at 12 months of age. The extreme values to Dermatophagoides farinae (W=31.73 SU·mL–1 and NW=68.9 SU·mL–1) were not plotted. Mean: solid line; Median: dotted line. Wilcoxon rank-sum test for D. pteronyssinus: p<0.01; D. farinae p<0.05.

Influence of family history for atopy onimmunoglobulin E levels and presence of recurrentwheezing
A positive family history for atopy was present in 53% (54 of 102) of the infants; 39% (21 of 54) of these developed recurrent wheezing and a positive maternal atopy was confirmed in 43% (9 of 21). In the group of infants without clinical manifestations, 61% (33 of 54) had a positive family history for atopy and 45% (15 of 33) had a positive maternal atopy. Total IgE levels and specific IgE levels were not influenced by positive family history for atopy in infants with and without recurrent wheezing, even if a maternal history for atopy was analysed separately.

	Discussion

TOP Abstract Material and methods Results Discussion Acknowledgements References

 
Wheezing infants had higher total IgE levels from birth up to 12 months of age. They were also sensitised to some food (egg white, cow's milk) and inhalant allergens (mites) at 6 and 12 months of age, with higher levels directed against these allergens at 12 months.

After birth, individuals with a genetic predisposition for atopy tend to present faster rises in serum IgE levels 7. Some authors have found that there is a higher risk for atopic disease when IgE concentrations exceed 10 IU·mL^–1 during the first year of life 8. In a cohort study of allergic and nonallergic children from 1 yr until adolescence, significant differences were observed in IgE levels between the two groups up to 11 yrs of age 9. In the present study, the mean IgE levels were significantly higher in infants with recurrent wheezing in all periods between birth and 1 yr of age. Nevertheless, low levels of IgE could not exclude later clinical manifestations of recurrent wheezing, because the concentrations varied considerably in this period of life. Furthermore, the broad overlap between IgE levels in atopic and nonatopic individuals decreases the clinical meaning of this laboratory measurement 10, 11. Thus, the present findings cannot ascertain the development of asthma in these wheezing infants solely by considering total IgE levels.

The exposure to an antigen, and the development of sensitisation may occur early, during late pregnancy. Some authors have documented proliferative responses of cord T-cells to some cow's milk proteins 12 or aeroallergens 13, 14. In the present study, high total IgE levels were found in cord blood, suggesting early sensitisation, probably by peptides that can gain access to the foetal circulation from the mother 15. Other hypotheses to explain high cord blood IgE levels involve environmental factors, including maternal smoking during pregnancy and season of birth. These factors act before birth contributing to the regulation of Th2 cells and IgE production 16.

The development of sensitisation to a specific allergen also varies with age 17. In a prospective study, specific IgE to egg white and cow's milk was found in infants starting from 3 months of age, and reached a peak prevalence at 8 months of age, while IgE for inhalants appeared from 2 yrs of age 18, 19. In this study, the majority of infants received this food early, and IgE responses to this food and to mite allergens were observed at the first measurement, at 6 months of age. Although these levels were higher in wheezing infants at 12 months, the statistical analyses performed were not used to evaluate enhanced risk of recurrent wheezing. It remains to be established whether these findings are part of an immune response associated with later development of atopy, or can be only a transient imbalance followed by maturation of the immune system 20. The evidence that IgE directed against egg white at 12 months of age is a valuable marker for subsequent allergic sensitisation to inhalant allergens 21, 22 argues the possibility that the present results could be associated with future atopic disease.

Immediate skin tests are widely used to identify sensitisation to a specific allergen and help in the diagnosis of atopic disease 23, 24. Skin tests for inhalant allergens may assist in the early diagnosis of asthma in wheezing infants 25. On the other hand, in children <3 yrs of age these tests can be unreliable, with a low positivity not correlating with specific IgE 26, 27, but others authors have shown that the skin-prick test is reliable with high positive correlation with specific IgE 28, 29. The present study showed a low number of wheezing infants with a positive test for inhaled allergens and no concordance with specific IgE levels. In addition, positive tests were found in the asymptomatic group. Thus, the limits of the interpretation of this test in infants must be considered. These include the relative hyporeactivity and thinness of infant skin, the low frequency of inhalant-specific IgE in early infancy, and the frequency of false-positive tests 23.

A great deal of effort has been invested in identifying early markers that will predict ongoing atopic asthma, but an accurate marker has not yet been found. In the first year of life, even a positive family history for atopy has a low sensitivity to identify who will continue to wheeze 30, 31. Although the association between high cord blood IgE levels and positive family history for atopy has been described (especially for maternal atopy 31, 32), in the present study, this association in cord blood was not confirmed. Similar results were found by Lilja et al. 33 in other periods during the first year of life.

Early recognition of asthma in wheezing infants is still a major problem for physicians. The only predictor of severe disease is pre-existing atopic eczema 34. Although the present authors could not define an atopic asthma marker, the specific immunoglobulin E levels to egg white may assist in diagnosis of atopy 12 months of age as shown in this and several other studies 21, 22. The results demonstrated that wheezing infants can present an immune response mediated by immunoglobulin E, suggesting an immunological imbalance. These alterations might suggest the hypothesis of a common defect in the ontogeny of the immune system involving immunoglobulin E production and early allergic sensitisation. A future follow-up of this cohort will provide more information regarding association with atopy.

	Acknowledgements

TOP Abstract Material and methods Results Discussion Acknowledgements References

 
The authors thank all collaborators who assisted in this research, especially C.M. Silva for her statistical assistance. The study was supported by Fundação de Amparo a Pesquisa do Estado de São Paulo (FAPESP).

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TOP Abstract Material and methods Results Discussion Acknowledgements References

 

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This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via ISI Web of Science (4) Citing Articles via Google Scholar Google Scholar Articles by Lopez, N. Articles by Ribeiro, J.D. Search for Related Content PubMed PubMed Citation Articles by Lopez, N. Articles by Ribeiro, J.D.