Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-27T13:23:31.319Z Has data issue: false hasContentIssue false

Short duration of breast-feeding as a risk-factor for β-cell autoantibodies in 5-year-old children from the general population

Published online by Cambridge University Press:  01 January 2007

Hanna Holmberg*
Affiliation:
Division of Paediatrics and Diabetes Research Centre, Department of Molecular and Clinical Medicine, Linköpings Universitet, Linköping, Sweden
Jeanette Wahlberg
Affiliation:
Division of Paediatrics and Diabetes Research Centre, Department of Molecular and Clinical Medicine, Linköpings Universitet, Linköping, Sweden
Outi Vaarala
Affiliation:
Division of Paediatrics and Diabetes Research Centre, Department of Molecular and Clinical Medicine, Linköpings Universitet, Linköping, Sweden Department of Viral Diseases and Immunology, Laboratory for Immunobiology, National Public Health Institute, Helsinki, Finland
Johnny Ludvigsson
Affiliation:
Division of Paediatrics and Diabetes Research Centre, Department of Molecular and Clinical Medicine, Linköpings Universitet, Linköping, Sweden
*
*Corresponding author: Ms. Hanna Holmberg, fax: +46 13 127465, email hanho@imk.liu.se
Rights & Permissions [Opens in a new window]

Abstract

Breast-feeding has been suggested to have a protective effect against the development of type 1 diabetes. In the present study, we investigated the relation between duration of breast-feeding and β-cell autoantibodies in 5-year-old non-diabetic children who participated in a prospective population-based follow-up study (the All Babies in Southeast Sweden study). Autoantibodies to insulin (IAA), glutamic acid decarboxylase (GADA) and the protein tyrosine phosphatase-like IA-2 (IA-2A) were measured by radiobinding assays. A short duration of total breast-feeding was associated with an increased risk of GADA and/or IAA above the ninety-fifth percentile at 5 years of age (OR 2·09, 95 % CI 1·45, 3·02; P < 0·000) as well as with an increased risk of IAA above the ninety-fifth percentile at this age (OR 2·89, 95 % CI 1·81, 4·62; P < 0·000). A short duration of exclusive breast-feeding was associated with an increased risk of GADA, IAA and/or IA-2A above the ninety-ninth percentile (OR 2·01, 95 % CI 1·08, 3·73; P = 0·028) as well as with an increased risk of IA-2A above the ninety-ninth percentile (OR 3·50, 95 % CI 1·38, 8·92; P = 0·009) at 5 years of age. An early introduction of formula was associated with an increased risk of GADA, IAA and/or IA-2A above the ninety-ninth percentile (OR 1·84, 95 % CI 1·01, 3·37; P = 0·047) at 5 years of age. The positive association between a short duration of both total and exclusive breast-feeding, as well as an early introduction of formula, and positivity for β-cell autoantibodies in children from the general population suggests that breast-feeding modifies the risk of β-cell autoimmunity, even years after finishing breast-feeding

Type
Research Article
Copyright
Copyright © The Authors 2007

Type 1 diabetes (T1D) is considered to be an autoimmune disease in which the insulin-producing β-cells are destroyed in genetically predisposed individuals (Castano & Eisenbarth, Reference Castano and Eisenbarth1990). Environmental factors are suggested to trigger the autoimmune response, as reviewed in Åkerblom et al. (Reference Åkerblom, Vaarala, Hyöty, Ilonen and Knip2002). In a number of studies, breast-feeding has been proposed to have a protective effect: a high frequency of breast-feeding has been reported to be associated with a low incidence of T1D (Borch-Johnsen et al. Reference Borch-Johnsen, Joner, Mandrup-Paulsen, Christy, Zachau-Christiansen and Kastrup1984; Dahl-Jorgensen et al. Reference Dahl-Jorgensen, Joner and Hanssen1991). A duration of breast-feeding of less than 3–4 months has been shown to be associated with development of T1D in a meta-analysis by Gerstein (Reference Gerstein1994). The possible protective effect of breast-feeding may be due to a delayed introduction of cows milk, and several studies have reported an earlier exposure to cows milk or solid foods in children with T1D compared with healthy children (Kostraba et al. Reference Kostraba, Cruickshanks, Lawler-Heavner, Jobim, Rewers, Gay, Chase, Klingensmith and Hamman1993; Verge et al. Reference Verge, Howard, Irwig, Simpson, Mackerras and Silink1994).

Most studies on the association between breast-feeding and T1D are retrospective, and the results may be compromised by recall bias. Thus, prospective studies are needed to investigate the possible association between β-cell autoimmunity, infant feeding in general and breast-feeding in particular. In a Finnish study, short-term exclusive breast-feeding and an early introduction of a cows milk-based formula were associated with an increased risk of β-cell autoimmunity in genetically predisposed children (Kimpimäki et al. Reference Kimpimäki, Erkkola, Korhonen, Kupila, Virtanen, Ilonen, Simell and Knip2001), but the duration of breast-feeding has not been associated with an increased risk of β-cell autoimmunity in children with a first-degree relative with T1D in Germany, Australia or the USA (Couper et al. Reference Couper, Steele and Beresford1999; Hummel et al. Reference Hummel, Füchtenbusch, Schenker and Ziegler2000; Norris et al. Reference Norris, Barriga, Klingensmith, Hoffman, Eisenbarth, Erlich and Rewers2003; Ziegler et al. Reference Ziegler, Schmid, Huber, Hummel and Bonifacio2003).

The protective effect of breast-feeding may also be due to the protective agents in the breast milk, which may affect the child's immature immune system, as reviewed in Newburg (Reference Newburg2005). In epidemiological studies, an increased risk of T1D has been associated with an early introduction of cows milk formula in infancy, indicating that triggering of the gut immune system in early infancy may contribute to the later development of β-cell autoimmunity (Vaarala, Reference Vaarala1999).

In predicting T1D, the presence of circulating autoantibodies to insulin (IAA) glutamic acid decarboxylase (GADA) and the protein tyrosine phosphatase-like IA-2 (IA-2A) are important, and multiple autoantibodies confer a higher risk of developing T1D (Bingley et al. Reference Bingley, Christie, Bonifacio, Bonfanti, Shattock, Fonte, Bottazzo and Gale1994; Verge et al. Reference Verge, Stenger, Bonifacio, Coleman, Pilcher, Bingley and Eisenbarth1998). We investigated the relation between duration of breast-feeding and β-cell autoantibodies in 5-year-old Swedish children from the general population who participated in a prospective population-based follow-up study (the All Babies in Southeast Sweden (ABIS) study).

Subjects and methods

Subjects

The current study was part of a prospective population-based follow-up study of all infants born between 1 October 1997 and 1 October 1999 in Southeast Sweden (the ABIS study; Ludvigsson et al. Reference Ludvigsson, Ludvigsson and Sepa2001). Data on total and exclusive breast-feeding, dietary factors, hereditary factors, delivery, infections and parents' age, education and ethnicity were obtained through questionnaires filled in at birth and 1, 2–3 and 5–6 years of age.

The duration of total breast-feeding was defined as the period when any breast milk was given regardless of other food supplements, and exclusive breast-feeding as the period when only breast milk was given. The duration of total breast-feeding was categorised into 0–3 months and 4 months or longer. The duration of exclusive breast-feeding was categorised 1–3 months and 4 months or longer.

The external factors of maternal age, maternal education, infections during pregnancy, mode of delivery, low birth weight ( < 2500 g), early age of gestation ( ≤ 37 weeks), a first-degree relative with T1D, coeliac disease (CD) or type 2 diabetes, or gastroenteritis in the child during the first year of life or recurrently until 5 years of age were considered as potential confounder variables and tested by the χ2 test.

Data regarding breast-feeding, the introduction of formula, external factors and additional background factors were available from questionnaires filled in at birth and 1-year, 2–3-year and 5–6-year follow-up. At the 5–6-year follow-up, data from questionnaires were available from 7443 families and a venous blood sample from 3788 children. The sera were stored at − 20°C until analysis of autoantibodies. The group of children with available questionnaire data at 5–6-year follow-up (n 7443) did not differ significantly from the group of children with available venous blood samples (n 3788) with regard to the additional background factors (mother's and father's age, educational level and ethnicity as well as T1D, type 2 diabetes and CD among first-degree relatives, or premature birth, low birth weight and delivery by caesarean section). Parents/guardians gave their informed consent, and the protocol of the ABIS study was approved by the Research Ethics Committees of the Medical Faculty of Linköpings Universitet, Linköping, and of the Medical Faculty of Lund University, Lund, Sweden.

Methods

Measurements of GADA and IA-2A by radiobinding assays were performed as previously described (Holmberg et al. Reference Holmberg, Vaarala, Sadauskaite-Kuehne, Ilonen, Padaiga and Ludvigsson2006). The cut-off for positivity at the ninety-ninth percentile of 5–6-year-old Swedish children was 160·9 relative units (RU)/ml, corresponding to 61·4 WHO units, for GADA (n 3251) and 5·6 RU/ml, corresponding to 4·0 WHO units, for IA-2A (n 3459). The cut-off for positivity at the ninety-fifth percentile for GADA was 62·3 RU/ml, corresponding to 20·9 WHO units. The cut-off for positivity was determined as the ninety-ninth percentile for IA-2A as the detection level of the IA-2A assay is 5·5 RU/ml. In the Diabetes Auto-antibody Standardization Program for the year 2005, at the ninety-ninth percentile the specificity was 99 % for GADA and 100 % for IA-2A, whereas the sensitivity was 74 % for GADA and 72 % for IA-2A. At the ninety-fifth percentile, the specificity for GADA was 94 % and the sensitivity 80 %. Interassay variation for negative and positive controls was 10 % and 8 % for GADA and 11 % and 12 % for IA-2A, respectively.

The measurement of IAA by radiobinding assays was performed according to the method of Williams et al. (Reference Williams, Bingley, Bonifacio, Palmer and Gale1997), with some modifications (Holmberg et al. Reference Holmberg, Vaarala, Sadauskaite-Kuehne, Ilonen, Padaiga and Ludvigsson2006). The cut-off for positivity at the ninety-ninth percentile of 2201 Swedish children (age 5–6 years) was 6·3 units/ml, and the cut-off for positivity at the ninety-fifth percentile was 2·6 units/ml. In the 2005 Diabetes Auto-antibody Standardization Program, at the ninety-ninth percentile, the specificity for IAA was 100 %, whereas the sensitivity was 24 %; the corresponding figures at the ninety-fifth percentile were 97 % and 34 %, respectively. Interassay variation for negative and positive controls was 11 % and 8 %, respectively. Standard curves and interpolated values of samples were performed using GraphPad Prism 4 (GraphPad Software Inc., San Diego, CA, USA).

In the present study, IAA levels above the ninety-fifth percentile or IA-2A above the ninety-ninth percentile was used as an outcome variable and marker of β-cell autoimmunity. In addition, GADA and/or IAA values above the ninety-fifth percentile or any one of GADA, IAA or IA-2A above the ninety-ninth percentile were used as outcome variables.

Statistics

The data from all the questionnaires were optically scanned. The data on breast-feeding in relation to autoantibody status have been analysed statistically using χ2 tests after classifying the children into autoantibody positive or negative. The duration of breast-feeding was divided into two categories. χ2 tests were also used to test the external factors and the additional background factors.

OR with 95 % CI were estimated using logistic regression with autoantibody positivity as the dependent variable and entering the significant variables. Autoantibodies as the dependent variable, and duration of either total or exclusive breast-feeding and the external factors as covariates, were analysed simultaneously and included in the multivariate model by stepwise forward selection for the significance of the explanatory variable. A P value below 0·05 and a 95 % CI not overlapping the null value 1·00 for the OR was regarded as statistically significant. Intercorrelations between variables were investigated using Spearman's rank correlation coefficients. A two-tailed P value of 0·05 or less was considered statistically significant. Calculations were performed with the statistical package SPSS 11.0 (SPSS Inc., Chicago, IL, USA).

Results

Descriptive

Among the 3788 children studied with autoantibody analysis, 12 (0·3 %) developed T1D before the age of 5–6 years and were therefore excluded from further analysis. Among the remaining 3776 non-diabetic children, the median duration of total breast-feeding was 8 months (data available on 2916 children) and that of exclusive breast-feeding was 4 months (data available on 2867 children). At 3 months of age, 2724/2916 (93·4 %) of the children were breast-fed and 2491/2867 (86·9 %) were exclusively breast-fed. Sixty-four of 3776 children (1·7 %) were positive for at least one of GADA, IA-2A and IAA above the ninety-ninth percentile, and 266/3776 children (7·0 %) were positive for GADA and/or IAA above the ninety-fifth percentile.

Breast-feeding and autoantibodies

The number of children positive for GADA and/or IAA above the ninety-fifth percentile was increased in children with a duration of total breast-feeding of less than 4 months compared with those breast-fed for longer (14·0 % and 7·2 %, respectively; P < 0·000). Similarly, the prevalence of IAA above the ninety-fifth percentile was higher in children with a duration of total breast-feeding less than 4 months compared with those breast-fed for longer (12·3 % and 4·6 %, respectively; P < 0·000). The number of children with GADA, IAA and/or IA-2A above the ninety-ninth percentile was non-significantly increased in children with a duration of total breast-feeding less than 4 months (3·0 % and 1·6 % for 0–3 months v. 4 months or longer; P = 0·090; Table 1). The number of children with IA-2A above the ninety-ninth percentile or IAA above the ninety-ninth percentile was not associated with the duration of total breast-feeding (data not shown). Similarly, the number of children with GADA above the ninety-fifth or ninety-ninth percentile was not associated with the duration of total breast-feeding (data not shown).

Table 1 Duration of total and exclusive breast-feeding in non-diabetic children with glutamic acid decarboxylase autoantibodies (GADA) and/or insulin autoantibodies (IAA) above the ninety-fifth percentile, IAA above the ninety-fifth percentile, GADA, IAA and/or protein tyrosine phosphatase-like (IA-2) autoantibodies (IA-2A) above the ninety-ninth percentile or IA-2A above the ninety-ninth percentile

A short duration of total breast-feeding was associated with an increased risk of GADA and/or IAA above the ninety-fifth percentile at 5 years of age (OR 2·09, 95 % CI 1·45, 3·02; P < 0·000) as well as with an increased risk of IAA above the ninety-fifth percentile at this age (OR 2·89, 95 % CI 1·81, 4·62; P < 0·000; Table 1).

The number of children positive for GADA and/or IAA above the ninety-fifth percentile was non-significantly increased in children with a duration of exclusive breast-feeding of less than 4 months (8·9 % and 6·9 % for 1–3 months v. 4 months or longer; P = 0·121). The number of children positive for IAA above the ninety-fifth percentile was also non-significantly increased in children with a duration of exclusive breast-feeding of under 4 months (6·5 % and 4·2 % for 1–3 months v. 4 months or longer; P = 0·070). The number of children with GADA, IAA and/or IA-2A above the ninety-ninth percentile was increased in children with a duration of exclusive breast-feeding of less than 4 months (2·7 % and 1·4 %, respectively; P = 0·025). The number of children with IA-2A above the ninety-ninth percentile was also increased in children with a duration of exclusive breast-feeding of less than 4 months (1·6 % and 0·5 %, respectively; P = 0·013; Table 1). The number of children with GADA above the ninety-fifth or ninety-ninth percentile, or IAA above the ninety-ninth percentile, was not associated with the duration of exclusive breast-feeding (data not shown).

A short duration of exclusive breast-feeding was associated with an increased risk of GADA, IAA and/or IA-2A above the ninety-ninth percentile (OR 2·01, 95 % CI 1·08, 3·73; P = 0·028), as well as with an increased risk of IA-2A above the ninety-ninth percentile (OR 3·50, 95 % CI 1·38, 8·92; P = 0·009) at 5 years of age (Table 1).

Introduction of cows milk proteins and autoantibodies

We also investigated whether the early introduction of cows milk protein in formula was associated with the development of β-cell autoantibodies. The duration of exclusive breast-feeding correlated to the age of exposure to formula (ρ = 0·591, P < 0·000). The majority of the non-diabetic children (1619/2675; 60·5 %) received formula for the first time at 5–9 months of age. In children who received formula early, at 1–3 months of age, the prevalence of GADA, IAA and/or IA-2A above the ninety-ninth percentile was increased compared with children who received formula later (2·4 % and 1·3 %, respectively; P = 0·043) and was associated with an increased risk of GADA, IAA and/or IA-2A above the ninety-ninth percentile (OR 1·84, 95 % CI 1·01, 3·37; P = 0·047). In children who received formula early, at 1–3 months of age, the prevalence of IAA above the ninety-fifth percentile was not significantly different from that of children who received formula later (6·1 % and 4·3 %, respectively; P = 0·1).

External factors and autoantibodies

The prevalence of the external factors (possible confounder variables) among the 3776 non-diabetic children is given in Table 2. The prevalence of IAA above the ninety-fifth percentile was higher in children with a first-degree relative with CD compared with those with no CD in the family (12·9 % and 4·9 %; respectively, P = 0·044). In a forward stepwise logistic regression with IAA as the dependent variable and duration of total breast-feeding and CD in the family as covariates, CD in the family did not affect the risk mediated by breast-feeding.

Table 2 Prevalence of external factors (possible confounder variables) among 3776 non-diabetic Swedish children

The prevalence of IA-2A above the ninety-ninth percentile was higher in children when the mother reported having an infection during pregnancy compared with those with no infection (1·1 % and 0·5 %, respectively; P = 0·051) and when the child was delivered via caesarean section compared with vaginal delivery (1·6 % and 0·5 %, respectively; P = 0·027). In a forward stepwise logistic regression with IA-2A as the dependent variable and the duration of exclusive breast-feeding and either infection during pregnancy or mode of delivery as covariates, neither of these affected the risk mediated by breast-feeding.

The prevalence of GADA and/or IAA above the ninety-fifth percentile tended to increase in children when the mother reported not having an infection during pregnancy compared with those with an infection (8·0 % and 6·0 %, respectively; P = 0·051). In a forward stepwise logistic regression with GADA and/or IAA as the dependent variable and duration of exclusive breast-feeding and infection during pregnancy as covariates, infection during pregnancy did not affect the risk mediated by breast-feeding.

All the other external variables mentioned earlier were found to be non-significant in χ2 tests with either IAA above the ninety-fifth percentile, IA-2A above the ninety-ninth percentile, GADA and/or IAA above the ninety-fifth percentile or GADA, IAA and/or IA-2A above the ninety-ninth percentile; they were therefore not included in any logistic regression analysis.

Discussion

We found a positive association between a short duration of total breast-feeding and positivity for GADA and/or IAA at the age of 5 years in non-diabetic children from the general population, which suggests that breast-feeding has a long-term effect on the risk of β-cell autoimmunity several years after completing breast-feeding. We also found a positive association between a short duration of exclusive breast-feeding, as well as the early introduction of formula, and positivity for GADA, IAA and/or IA-2A at the age of 5 years in non-diabetic children.

The risk of T1D associated with short breast-feeding (less than 4 months) may be mediated by a diabetogenic effect of cows milk formula, which is usually used for weaning, or by a protective effect of breast milk itself. As breast milk contains growth factors and cytokines, it promotes the maturation of the intestinal mucosa, and the protective effect of breast-feeding might be explained by an improved function of the gut immune system, as reviewed in Harrison & Honeyman (Reference Harrison and Honeyman1999). Immunisation to bovine insulin in cows milk has been suggested to be the link explaining the cows milk-mediated risk of T1D in children with aberrant function of the gut immune system (Vaarala, Reference Vaarala1999; Knip et al. Reference Knip, Veijola, Virtanen, Hyöty, Vaarala and Åkerblom2005).

Insulin is an important autoantigen, especially in young children who develop T1D, as autoantibodies to insulin (IAA) are often the first autoantibody detected in the young children (Ziegler et al. Reference Ziegler, Hummel, Schenker and Bonifacio1999) and the prevalence of IAA is highest in the youngest children (Arslanian et al. Reference Arslanian, Becker, Rabin, Atchison, Eberhardt, Cavender, Dorman and Drash1985; Karjalainen et al. Reference Karjalainen, Knip, Mustonen, Ilonen and Akerblom1986; Vardi et al. Reference Vardi, Ziegler and Mathews1988). Although a short duration of total breast-feeding was associated specifically with IAA, suggesting a link with insulin, we observed only a weak positive association between IAA and the duration of exclusive breast-feeding and early exposure to cows milk formula in the Swedish population. Instead, the combination of GADA, IAA and/or IA-2A was associated with both a short duration of exclusive breast-feeding and an early introduction of formula.

Exposure to dietary factors introduced at the weaning, such as cows milk formula, is lower if breast-feeding is still continued. Infants with a short duration of total breast-feeding (i.e. those who are breast-fed for less than 4 months) have therefore been exposed to higher doses of cows milk formula at the age of 3 months than those infants who have been reported to have a duration of exclusive breast-feeding of less than 4 months. This kind of dose-effect was seen in our previous study (Vaarala et al. Reference Vaarala, Klemetti, Juhela, Simell, Hyöty and Ilonen2002). In addition, in studies on the risk of CD, children with CD were exposed to a larger amount of gluten at first exposure than children without CD (Ivarsson et al. Reference Ivarsson, Hernell, Stenlund and Persson2002).

In previous studies of children with an increased genetic risk of T1D (Norris et al. Reference Norris, Barriga, Klingensmith, Hoffman, Eisenbarth, Erlich and Rewers2003) or a first-degree relative with T1D (Couper et al. Reference Couper, Steele and Beresford1999; Ziegler et al. Reference Ziegler, Schmid, Huber, Hummel and Bonifacio2003), no association was found between duration of either total or exclusive breast-feeding and β-cell autoimmunity. In addition, the early introduction of food supplements containing cows milk did not increase the risk of β-cell autoimmunity (Norris et al. Reference Norris, Barriga, Klingensmith, Hoffman, Eisenbarth, Erlich and Rewers2003; Ziegler et al. Reference Ziegler, Schmid, Huber, Hummel and Bonifacio2003). Prospective studies in Germany (Ziegler et al. Reference Ziegler, Schmid, Huber, Hummel and Bonifacio2003) and the USA (Norris et al. Reference Norris, Barriga, Klingensmith, Hoffman, Eisenbarth, Erlich and Rewers2003) did not reveal any association between duration of breast-feeding or early introduction of cows milk and β-cell autoimmunity, as in the Finnish study (Kimpimäki et al. Reference Kimpimäki, Erkkola, Korhonen, Kupila, Virtanen, Ilonen, Simell and Knip2001) as well as the present one.

The different findings in these studies may be due to differences in the populations or may reflect different infant-feeding practices in different countries. When weaning to formula in Germany and the USA, a hydrolysed formula is often used (Åkerblom et al. Reference Åkerblom, Virtanen and Ilonen2005), which is less immunogenic (Vaarala et al. Reference Vaarala, Saukkonen, Savilahti, Klemola and Åkerblom1995). This kind of formula is less often used in Sweden (according to the recommendations of the National Board of Health and Welfare) and Finland (Åkerblom et al. Reference Åkerblom, Virtanen and Ilonen2005). The high frequency of children receiving breast milk at 3 months of age in our study cohort correlates with numbers from the whole ABIS study population (Brekke et al. Reference Brekke, Ludvigsson, van Odijk and Ludvigsson2005), as well as the National Board of Health and Welfare (Official Statistics of Sweden, 2000). It is extremely difficult to dissect the effect of different mediators in the pathogenic process leading to the manifestation of disease or the appearance of surrogate markers such as β-cell autoimmunity for T1D.

We do not expect a large number of children with T1D in our study population at this age so the end-point is β-cell autoimmunity. One may speculate whether this β-cell autoimmunity is transient or whether the aetiology differs from that of T1D. It is possible that environmental factors triggering the initial β-cell autoimmunity are different from those which later cause the ensuing T1D, as recently suggested (Knip et al. Reference Knip, Veijola, Virtanen, Hyöty, Vaarala and Åkerblom2005). Despite this, the environmental factors that trigger the β-cell autoimmunity determine the population at risk of T1D. Additional studies may shed light on the importance of these factors, such as a short duration of breast-feeding, in the progression from β-cell autoimmunity to clinical disease.

Acknowledgements

We thank all the children and parents who participated in the ABIS project. We also thank Lena Berglert, Gosia Smolinska, Ingela Johansson and Cecilia Runnqvist for help in autoantibody determinations, Mickaela Samuelsson for administrative work and research nurses Christina Larsson and Iris Franzén, as well as all the local study nurses. This study, as part of the ABIS project, was supported by JDRF-Wallenberg foundations (K 98-99JD-12 813-01A), the Swedish Medical Research Council (MFR; Vetenskapsrådet, K99-72X-11 242-05A), the Swedish Child Diabetes Foundation (Barndiabetesfonden) and the Medical Research Found of the County of Östergötland.

References

Åkerblom, HK, Vaarala, O, Hyöty, H, Ilonen, J & Knip, M (2002) Environmental factors in the etiology of type 1 diabetes. Am J Med Genet Semin Med Genet 115, 1829CrossRefGoogle ScholarPubMed
Åkerblom, HK, Virtanen, SM, Ilonen, J, et al. (2005) Dietary manipulation of beta cell autoimmunity in infants at increased risk of type 1 diabetes: a pilot study. Diabetologia 48, 829837CrossRefGoogle ScholarPubMed
Arslanian, SA, Becker, DJ, Rabin, B, Atchison, R, Eberhardt, M, Cavender, D, Dorman, J & Drash, AL (1985) Correlates of insulin antibodies in newly diagnosed children with insulin-dependent diabetes before insulin therapy. Diabetes 34, 926930CrossRefGoogle ScholarPubMed
Bingley, PJ, Christie, MR, Bonifacio, E, Bonfanti, R, Shattock, M, Fonte, M-T, Bottazzo, G-F & Gale, EAM (1994) Combined analysis of autoantibodies improves prediction of IDDM in islet cell antibody positive relatives. Diabetes 43, 13041310CrossRefGoogle ScholarPubMed
Borch-Johnsen, K, Joner, G, Mandrup-Paulsen, T, Christy, M, Zachau-Christiansen, B & Kastrup, K (1984) Relation between breast-feeding and incidence rates of insulin-dependent diabetes mellitus: a hypothesis. Lancet 10, 10831086CrossRefGoogle Scholar
Brekke, HK, Ludvigsson, JF, van Odijk, J & Ludvigsson, J (2005) Breastfeeding and introduction of solid foods in Swedish infants: the All Babies in Southeast Sweden study. Br J Nutr 94, 377382CrossRefGoogle ScholarPubMed
Castano, L & Eisenbarth, GS (1990) Type 1 diabetes: a chronic disease of human, mouse and rat. Annu Rev Immunol 8, 647679CrossRefGoogle ScholarPubMed
Couper, JJ, Steele, C, Beresford, S, et al. (1999) Lack of association between duration of breast-feeding or introduction of cow's milk and development of islet autoimmunity. Diabetes 48, 21452149CrossRefGoogle ScholarPubMed
Dahl-Jorgensen, K, Joner, G & Hanssen, KF (1991) Relationship between cows' milk consumption and incidence of IDDM in childhood. Diabetes Care 14, 10811083CrossRefGoogle ScholarPubMed
Gerstein, HC (1994) Cow's milk exposure and type 1 diabetes mellitus. Diabetes Care 17, 1319CrossRefGoogle Scholar
Harrison, LC & Honeyman, MC (1999) Cow's milk and type 1 diabetes: the real debate is about mucosal immune function. Diabetes 48, 15011507CrossRefGoogle ScholarPubMed
Holmberg, H, Vaarala, O, Sadauskaite-Kuehne, V, Ilonen, J, Padaiga, Z & Ludvigsson, J (2006) Higher prevalence of autoantibodies to insulin and GAD65 in Swedish compared to Lithuanian children with type 1 diabetes. Diabetes Res Clin Pract 72, 308314CrossRefGoogle ScholarPubMed
Hummel, M, Füchtenbusch, M, Schenker, M & Ziegler, A-G (2000) No major association of breast-feeding, vaccinations, and childhood viral diseases with early islet autoimmunity in the German BABYDIAB study. Diabetes Care 23, 969974CrossRefGoogle ScholarPubMed
Ivarsson, A, Hernell, O, Stenlund, H & Persson, LA (2002) Breast-feeding protects against celiac disease. Am J Clin Nutr 75, 914921CrossRefGoogle ScholarPubMed
Karjalainen, J, Knip, M, Mustonen, A, Ilonen, J & Akerblom, HK (1986) Relation between insulin antibody and complement-fixing islet cell antibody at clinical diagnosis of IDDM. Diabetes 35, 620622CrossRefGoogle ScholarPubMed
Kimpimäki, T, Erkkola, M, Korhonen, S, Kupila, A, Virtanen, SM, Ilonen, J, Simell, O & Knip, M (2001) Short-term exclusive breastfeeding predisposes young children with increased genetic risk of type 1 diabetes to progressive beta-cell autoimmunity. Diabetologia 44, 6369Google ScholarPubMed
Knip, M, Veijola, R, Virtanen, SM, Hyöty, H, Vaarala, O & Åkerblom, HK (2005) Environmental triggers and determinants of type 1 diabetes. Diabetes 54, S125S136CrossRefGoogle ScholarPubMed
Kostraba, JN, Cruickshanks, KJ, Lawler-Heavner, J, Jobim, LF, Rewers, MJ, Gay, EC, Chase, HP, Klingensmith, G & Hamman, RF (1993) Early exposure to cow's milk and solid foods in infancy, genetic predisposition, and risk of IDDM. Diabetes 42, 288295CrossRefGoogle ScholarPubMed
Ludvigsson, J, Ludvigsson, M & Sepa, A (2001) Screening for prediabetes in the general child population: maternal attitude to participation. Pediatr Diabetes 2, 170174CrossRefGoogle ScholarPubMed
Newburg, DS (2005) Innate immunity and human milk. J Nutr 135, 13081312CrossRefGoogle ScholarPubMed
Norris, JM, Barriga, K, Klingensmith, G, Hoffman, M, Eisenbarth, GS, Erlich, HA & Rewers, M (2003) Timing of initial cereal exposure in infancy and risk of islet autoimmunity. JAMA 290, 17131720CrossRefGoogle ScholarPubMed
Official Statistics of Sweden (2000) Statistics – Health and Disease: Breast-feeding, Children Born 1998. Stockholm: National Board of Health and Welfare Centre for EpidemiologyGoogle Scholar
Vaarala, O (1999) Gut and the induction of immune tolerance in type 1 diabetes. Diabetes Metab Res Rev 15, 3533613.0.CO;2-4>CrossRefGoogle ScholarPubMed
Vaarala, O, Klemetti, P, Juhela, S, Simell, O, Hyöty, H & Ilonen, J (2002) Effect of coincident enterovirus infection and cow's milk exposure on immunisation to insulin in early infancy. Diabetologia 45, 531534CrossRefGoogle ScholarPubMed
Vaarala, O, Saukkonen, T, Savilahti, E, Klemola, T & Åkerblom, HK (1995) Development of immune response to cow's milk proteins in infants receiving cow's milk or hydrolysed formula. J Allergy Clin Immunol 96, 917923CrossRefGoogle ScholarPubMed
Vardi, P, Ziegler, AG, Mathews, JH, et al. (1988) Concentration of insulin autoantibodies at onset of type I diabetes. Inverse log-linear correlation with age. Diabetes Care 11, 736739CrossRefGoogle ScholarPubMed
Verge, C, Howard, N, Irwig, L, Simpson, J, Mackerras, D & Silink, M (1994) Environmental factors in childhood IDDM. A population-based, case-control study. Diabetes Care 17, 13811389CrossRefGoogle ScholarPubMed
Verge, CF, Stenger, D, Bonifacio, E, Coleman, PG, Pilcher, C, Bingley, PJ & Eisenbarth, GS& participating laboratories (1998) Combined use of autoantibodies (IA-2ab, GADab, IAA, ICA) in type I diabetes: combinatorial islet autoantibody workshop. Diabetes 47, 18571866CrossRefGoogle Scholar
Williams, AJK, Bingley, PJ, Bonifacio, E, Palmer, JP & Gale, EAM (1997) A novel micro-assay for insulin autoantibodies. J Autoimmun 10, 473478CrossRefGoogle ScholarPubMed
Ziegler, AG, Hummel, M, Schenker, M & Bonifacio, E (1999) Autoantibody appearance and risk for development of childhood diabetes in offspring of parents with type 1 diabetes: the 2-year analysis of the German BABYDIAB Study. Diabetes 48, 460468CrossRefGoogle ScholarPubMed
Ziegler, AG, Schmid, S, Huber, D, Hummel, M & Bonifacio, E (2003) Early infant feeding and risk of developing type 1 diabetes-associated autoantibodies. JAMA 290, 17211728CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Duration of total and exclusive breast-feeding in non-diabetic children with glutamic acid decarboxylase autoantibodies (GADA) and/or insulin autoantibodies (IAA) above the ninety-fifth percentile, IAA above the ninety-fifth percentile, GADA, IAA and/or protein tyrosine phosphatase-like (IA-2) autoantibodies (IA-2A) above the ninety-ninth percentile or IA-2A above the ninety-ninth percentile

Figure 1

Table 2 Prevalence of external factors (possible confounder variables) among 3776 non-diabetic Swedish children