Human Milk Fatty Acid Composition of Allergic and Non-Allergic Mothers: The Ulm SPATZ Health Study
by
, , ,
Linda P. Siziba
1,*
,
Leonie Lorenz
2,
Bernd Stahl
3,4,
Marko Mank
3,
Tamas Marosvölgyi
5
,
Tamas Decsi
5,
Dietrich Rothenbacher
2 and
Jon Genuneit
1,2 1
Pediatric Epidemiology, Department of Pediatrics, Medical Faculty, Leipzig University, 04103 Leipzig, Germany
2
Institute of Epidemiology and Medical Biometry, Ulm University, 89075 Ulm, Germany
3
Danone Nutricia Research, 3584 CT Utrecht, The Netherlands
4
Department of Chemical Biology & Drug Discovery, Utrecht Institute for Pharmaceutical Sciences, Utrecht University, 3584 CG Utrecht, The Netherlands
5
Department of Paediatrics, Medical School, University of Pécs, H-7623 Pécs, Hungary
*
Author to whom correspondence should be addressed.
Nutrients 2020, 12(6), 1740; https://doi.org/10.3390/nu12061740
Submission received: 8 May 2020
/
Revised: 29 May 2020
/
Accepted: 7 June 2020
/
Published: 10 June 2020
(This article belongs to the Section Nutritional Epidemiology)
Abstract
:The aim of this study was to determine the differences in human milk fatty acid composition in relation to maternal allergy within a large birth cohort study using statistical methods accounting for the correlations that exist in compositional data. We observed marginal differences in human milk fatty acid composition of allergic and non-allergic mothers. However, our results do not support the hypothesis that human milk fatty acid composition is influenced by allergy or that it differs between mothers with or without allergy. Observed differences in our results between transformed and untransformed fatty acid data call for re-evaluation of previous, as well as future, studies using statistical methods appropriate for compositionality of fatty acid data.
1. Introduction
Human milk contains a variety of nutrients, immunological and biological components necessary for growth and development of infants [1]. While human milk is considered the gold standard in early life nutrition, allergens, which may cause allergic reactions in atopic or allergic infants, can also be transferred through human milk [2]. Of great interest are fatty acids which have also been proposed to have immune-regulatory properties and could be involved in the etiology of allergic disease [3]. The essential fatty acids, linoleic acid (LA, C18:2n-6) and α-linoleic acid (ALA, C18:3n-3), are metabolized into long-chain polyunsaturated fatty acids (LCPUFAs) by the same set of desaturase and elongase enzymes [3].
In this regard, an impaired function of the delta-6-desaturase (D6D) enzyme converting LA and ALA to their long-chain metabolites has been implicated in atopic disease mechanisms. Several studies have found low concentrations of n-6 LCPUFAs in human milk of mothers with allergic disease [4,5,6], while other studies observed very little to no differences at all [1,7,8,9,10,11,12]. These studies compared human milk fatty acid composition of small subgroups, selected individuals or total fatty acids and did not account for existing correlations within compositional data. We, therefore, aimed at determining the differences in human milk fatty acid composition in relation to maternal allergy within a large birth cohort using statistical methods accounting for the constant sum constraint.
2. Materials and Methods
2.1. Study Design and Population
The Ulm SPATZ Health Study recruited a total of 1006 newborns and their 970 mothers (67% of all 1593 eligible families) from the general population during their hospital stay soon after delivery in the University Medical Center, Ulm, southern Germany, between April 2012 and May 2013. Details about the study can be found elsewhere [13]. Exclusion criteria were inadequate German language skills, outpatient childbirth, maternal age <18 years, postpartum transfer of mother or child to an intensive care unit, or stillbirth. Participation in the study was voluntary and informed consent was obtained from each study participant. Ethical approval was obtained from the Ethics Board of Ulm University (No. 311/11).
2.2. Data Collection and Measurements
Demographic information and maternal history of allergic disease (hay fever, asthma or atopic dermatitis) were collected using a self-administered questionnaire. Maternal allergy was self-reported and classified as mothers who reported a history of physician-diagnosed hay fever, neurodermatitis or asthma. Non-allergic mothers were classified as mothers who reported the absence of an allergic disease. Additional information was collected at approximately 6 weeks, 6 months and 12 months post-delivery through telephone interviews or postal self-administered questionnaires. The use of medication was assessed using an open questionnaire and the clear text entries were used to code and determine the use of allergy medication. Human milk samples were collected at approximately 6 weeks, 6 months and 12 months of lactation. Mothers were asked to manually express or pump breast milk between 9 am and 12 pm, after breakfast but before lunch and at least one hour after the last feed of the infant to reduce possible variations resulting from times of expression and feed. Human milk samples were stored at −80 °C until analysis of fatty acids between 2015 and 2018, as explained previously [13].
2.3. Statistical Analysis
Centered log ratio (CLR) transformations were applied to fatty acid data to account for compositionality [13]. Principal component analysis was used to evaluate associations of maternal allergy with possible fatty acid groups based on their correlational properties. The associations of maternal allergy with individual fatty acid concentrations were estimated using multiple linear regressions. Bonferroni adjustment was applied to account for multiple testing. Bonferroni correction dramatically reduces the probability of finding a significant result based on the number of tests performed. However, this also reduces the risk of making excessive assertions in clinical research [14]. All statistical analyses were performed with SAS version 9.4 (the SAS Institute, Cary, NC, USA).
3. Results
3.1. Characteristics of the Lactating Mothers
Of the 970 mothers enrolled into the SPATZ study, we included 475 lactating mothers with human milk samples available at both 6 weeks and 6 months. More than a third (36.2%, n = 175) reported a history of allergy. The lactating mothers were aged 33.5 ± 4.1 years and their characteristics are shown in Table 1. Of the lactating mothers who reported a history of allergy, n = 26 were on allergy medication.
3.2. Fatty Acid Composition in Human Milk of Allergic and Non-Allegic Mothers
The fatty acid composition of human milk samples collected at 6 weeks and 6 months was compared between allergic and non-allergic mothers. No significant differences were observed at 6 weeks of lactation. At 6 months, the CLR-transformed constituent sizes of the n-6 metabolites dihomo-γ-linolenic acid (DGLA, C20:3n-6; p = 0.0136), arachidonic acid (AA, C20:4n-6; p = 0.0359) and Osbond acid (C22:5n-6; p = 0.0134) were lower in mothers with allergic disease compared with their non-allergic counterparts (Table 2), but not statistically significant following Bonferroni correction (threshold α = 0.0009). Small differences were also observed when comparing untransformed relative proportions of fatty acids in human milk of allergic mothers to their non-allergic counterparts (Supplementary Table S1). Principal component analysis results did not show any clear associations of any maternal indicator with overall human milk fatty acid composition at any time point.
3.3. Associations between Human Milk Fatty Acid Composition and Maternal Allergy
Lactating mothers were stratified according to a specific allergic disease, i.e., asthma, hay fever or atopic dermatitis. We then investigated the associations between individual CLR-transformed fatty acids with asthma, hay fever and atopic dermatitis. Following adjustments for age, parity and pre-pregnancy BMI, the constituents of DGLA (β = 0.029, p = 0.0141) measured at 6 weeks were positively associated with maternal atopic dermatitis, while the constituents of DGLA (β = −0.015, p = 0.0105), AA (β = −0.003, p = 0.0186) and total n-6 LCPUFA (β = −0.043, p = 0.0125) measured at 6 months were negatively associated with maternal hay fever. In addition, at 6 weeks, the constituents of ALA (C18:3n-3; β = 0.176, p = 0.0065), dihomo-α-linolenic acid (C20:3n-3; β = 0.006, p = 0.0057) and total n-3 polyunsaturated fatty acids (PUFAs; β = 0.180, p = 0.0289) were positively associated with maternal asthma while LA (C18:2n-6; β = −0.011, p = 0.0481) was negatively associated with maternal asthma. D6D activity, calculated as the product/precursor ratio (18:2n-6/18:3n-6), was negatively associated with maternal asthma at both 6 weeks (β = −0.002, p = 0.0086) and 6 months (β = −0.002, p = 0.0079). However, these effect sizes were very small and all these associations lost significance following Bonferroni correction (threshold α = 0.0009).
4. Discussion
In the present study, we investigated the differences in human milk fatty acid composition of allergic and non-allergic mothers, sampled at both 6 weeks and 6 months. Our results suggest an impaired D6D enzyme activity converting LA to γ-linoleic acid (GLA) in allergic mothers. However, these associations were marginal and lost significance following correction for multiple testing. Therefore, these small differences could be driven by other factors that were not measured in this study.
Human milk fatty acid composition is driven by many factors and is also greatly influenced by gene variants of the fatty acid desaturase (FADS) gene cluster [15]. Lattka and colleagues [16] previously observed significant associations between the FADS genotype and AA contents in human milk as well as the ratio between AA and DGLA in the Ulm Birth Cohort Study (UBCS). Their results suggest a possible indication of the impact of FADS genotypes on the LCPUFA contents in human milk. In light of this, the UBCS and the Ulm SPATZ Health studies are similar with regards to both methodologies and population characteristics [17]. Therefore, we attribute these small differences that we observed to the genetic variation modulating the rate of endogenous synthesis on LCPUFAs.
Nonetheless, we cannot rule out the potential influence of other biological human milk components as well as dietary intake. Although we did not assess dietary intake, the lactating mothers in this study were highly educated and presumably of higher social economic status, thus it is plausible that they were taking some LCPUFA supplements which could have contributed to the differences in fatty acid composition. In addition, previous reports [1,4,5,6,7,8,9,10,12,18] on differences in human milk fatty acid composition between non-allergic and allergic mothers show conflicting results. Similar to some studies [4,6,9,18], very small but significant differences were also observed when untransformed (relative proportions and/or absolute values of fatty acids) fatty acids were used to assess associations with asthma, hay fever and neurodermatitis. Thus, the observed differences in our results between CLR-transformed and -untransformed fatty acid data call for re-evaluation of previous studies using statistical methods appropriate for compositionality of fatty acid data. On one hand, even small differences in fatty acid composition of some lipid pools may have some physiological relevance in the etiology of disease and physiological aspects during infancy [3]. Although the influence of human milk fatty acid composition on child allergy has been studied extensively [19], whether the small differences observed in our study are associated with the development of an allergy in allergic infants of the respective mothers is yet to be studied. On the other hand, the mechanisms underlying the altered fatty acid compositions that exist in some groups of atopic individuals remain understudied. Therefore, unless these mechanisms are understood, it would be untimely to promote interventions that will influence fatty acid composition of allergic mothers as these may be ineffective [3].
The limitations of the study include the fact that we did not assess dietary intake during lactation as well as the lack of other parameters potentially relevant for this study as this may have influenced some of the fatty acid profiles. In addition, the number of lactating mothers on allergy medication was very low (n = 26) and we could not distinguish between active, chronic or acute allergy and whether or not the lactating mothers were in remission. Thus, granted that the timing of exposure is an important aspect which we could not measure in our study, our results should be interpreted with caution. Moreover, we cannot exclude the possibility of misclassification of the maternal history of allergy, as this was self-reported via questionnaires and included mothers with active and non-active allergic disease.
5. Conclusions
In conclusion, our data do no support the hypothesis that human milk fatty acid composition is influenced by maternal allergy or that it differs between mothers with or without allergy. The small differences that we observed in this study could be ascribed to dietary habits, genetic factors and possibly other biological components in human milk. The conflicting results from previous studies also show the importance of studies that evaluate specific components in human milk and their biological role in infant and child health. Therefore, future studies including more homogenous groups of mothers with an active allergy are needed to investigate whether there are indeed differences and whether these differences have an impact on atopic sensitization in the infant.
Supplementary Materials
The following are available online at https://www.mdpi.com/2072-6643/12/6/1740/s1, Table S1: Means and standard deviations (mean (SD)) of relative proportions (%) of total fatty acid concentrations in human milk sampled at 6 weeks and 6 months of lactation in the Ulm SPATZ Health Study.
Author Contributions
L.P.S. and J.G. conceived the study question. L.P.S. conducted the statistical analyses. L.L. contributed to the statistical analyses. L.P.S. and J.G. interpreted the data and wrote the Communication. T.M. and T.D. analyzed the fatty acids in the lab. J.G. and D.R. conceived and designed the Ulm SPATZ Health Study. All authors including (B.S. and M.M.) critically reviewed the manuscript and contributed to its final version. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by Danone Nutricia Research.
Acknowledgments
The authors would like to express their utmost gratitude to the midwives, nurses and obstetricians of the Department of Gynecology and Obstetrics, University Medical Center Ulm, the pediatricians, mothers and their families for their study support and participation. Further thanks to Gisela Breitinger and Christa Johanna Knaus for providing excellent technical assistance.
Conflicts of Interest
The funders had no role in the study design, in the collection, analysis and interpretation of data. The funders had no role in the final decisions on the interpretation and dissemination of the results.
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Table 1.
Characteristics of allergic and non-allergic lactating women included in the Ulm SPATZ Health Study.
Table 1.
Characteristics of allergic and non-allergic lactating women included in the Ulm SPATZ Health Study.
| Characteristic | All Women (n = 475) | Allergy (n = 172) | No Allergy (n = 303) | |||
|---|---|---|---|---|---|---|
| N | % or Mean | n | % or Mean | n | % or Mean | |
| Age | 475 | 33.5 | 172 | 33.9 | 303 | 33.2 |
| Parity | ||||||
| 0 births | 245 | 51.6% | 80 | 46.5% | 165 | 54.5% |
| ≥ 1 birth | 230 | 48.4% | 92 | 53.5% | 138 | 45.5% |
| Education | ||||||
| Low | 14 | 3.0% | 5 | 2.9% | 9 | 3.0% |
| Intermediate | 117 | 24.9% | 37 | 21.8% | 80 | 26.8% |
| High | 338 | 72.1% | 128 | 75.3% | 210 | 70.2% |
| Maternal BMI at 6 weeks | ||||||
| Underweight (BMI < 18.50) | 3 | 0.7% | 2 | 1.3% | 1 | 0.4% |
| Normal (18.50 ≤ BMI < 25.00) | 262 | 59.7% | 88 | 55.7% | 174 | 61.9% |
| Overweight (25.00 ≤ BMI < 30.00) | 131 | 29.8% | 47 | 29.7% | 84 | 29.9% |
| Obese (BMI ≥ 30.00) | 43 | 9.8% | 21 | 13.3% | 22 | 7.8% |
| Maternal Allergy | ||||||
| Yes | 172 | 36.2% | 172 | 100.0% | 303 | 100.0% |
| No | 303 | 63.8% | ||||
| Asthma | ||||||
| Yes | 38 | 8.0% | 38 | 22.1% | ||
| No | 437 | 92.0% | 134 | 77.9% | 303 | 100.0% |
| Hay fever | ||||||
| Yes | 120 | 25.3% | 120 | 69.8% | ||
| No | 355 | 74.7% | 52 | 30.2% | 303 | 100.0% |
| Neurodermatitis | ||||||
| Yes | 67 | 14.1% | 67 | 39.0% | ||
| No | 408 | 85.9% | 105 | 61.0% | 303 | 100.0% |
BMI—body mass index. Sums may not always add up to total because certain items were missing. Percentages exclude those missing items.
Table 2.
Means and standard deviations (mean (SD)) of centered log ratio (CLR)-transformed fatty acid concentrations of human milk samples measured at 6 weeks and 6 months of lactation.
Table 2.
Means and standard deviations (mean (SD)) of centered log ratio (CLR)-transformed fatty acid concentrations of human milk samples measured at 6 weeks and 6 months of lactation.
| Fatty Acid | All 6 Weeks Samples (n = 475) | Allergy (n = 172) | No Allergy (n = 303) | p | All 6 Months Samples (n = 475) | Allergy (n = 172) | No Allergy (n = 303) | p | |||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| SFAs | 3.47 | (0.13) | 3.48 | (0.15) | 1.16 | (0.12) | 0.9853 | 3.58 | (0.13) | 3.59 | (0.14) | 3.58 | (0.13) | 0.7641 | |
| C8:0 | Caprylic | 0.19 | (0.52) | 0.17 | (0.68) | 0.20 | (0.41) | 0.9653 | 0.28 | (0.36) | 0.29 | (0.34) | 0.28 | (0.37) | 0.9731 |
| C10:0 | Capric | 2.25 | (0.30) | 2.24 | (0.32) | 2.25 | (0.29) | 0.7934 | 2.33 | (0.29) | 2.32 | (0.29) | 2.33 | (0.28) | 0.7049 |
| C11:0 | Undecylic | −2.32 | (0.31) | −2.34 | (0.30) | −2.31 | (0.31) | 0.3613 | −2.27 | (0.29) | −2.27 | (0.30) | −2.27 | (0.29) | 0.8034 |
| C12:0 | Lauric | 3.39 | (0.34) | 3.39 | (0.37) | 3.39 | (0.33) | 0.8125 | 3.61 | (0.31) | 3.60 | (0.32) | 3.62 | (0.30) | 0.4720 |
| C13:0 | Tridecylic | −1.58 | (0.24) | −1.59 | (0.23) | −1.58 | (0.24) | 0.5101 | −1.47 | (0.28) | −1.46 | (0.24) | −1.48 | (0.30) | 0.9892 |
| C14:0 | Myristic | 3.54 | (0.22) | 3.53 | (0.24) | 3.55 | (0.22) | 0.3139 | 3.77 | (0.23) | 3.77 | (0.23) | 3.78 | (0.23) | 0.6136 |
| C15:0 | Pentadecylic | 0.81 | (0.23) | 0.80 | (0.23) | 0.81 | (0.24) | 0.5808 | 0.86 | (0.23) | 0.85 | (0.23) | 0.87 | (0.23) | 0.3542 |
| C16:0 | Palmitic | 4.88 | (0.15) | 4.89 | (0.16) | 4.88 | (0.14) | 0.2241 | 4.93 | (0.14) | 4.93 | (0.13) | 4.93 | (0.14) | 0.5410 |
| C17:0 | Margaric | 0.59 | (0.17) | 0.59 | (0.17) | 0.60 | (0.17) | 0.4968 | 0.66 | (0.15) | 0.66 | (0.15) | 0.66 | (0.16) | 0.8611 |
| C18:0 | Stearic | 3.68 | (0.23) | 3.70 | (0.27) | 3.67 | (0.21) | 0.2180 | 3.76 | (0.22) | 3.78 | (0.22) | 3.75 | (0.22) | 0.0409 |
| C19:0 | Nonadecylic | −1.85 | (0.24) | −1.83 | (0.24) | −1.85 | (0.24) | 0.2386 | −1.79 | (0.35) | −1.78 | (0.43) | −1.80 | (0.29) | 0.2133 |
| C20:0 | Arachidic | 0.15 | (0.24) | 0.18 | (0.28) | 0.14 | (0.22) | 0.0958 | 0.20 | (0.23) | 0.23 | (0.24) | 0.18 | (0.23) | 0.0370 |
| C22:0 | Behenic | −0.72 | (0.24) | −0.71 | (0.25) | −0.72 | (0.24) | 0.6782 | −0.67 | (0.26) | −0.65 | (0.29) | −0.67 | (0.25) | 0.8018 |
| C23:0 | Tricosylic | −4.29 | (2.10) | −4.36 | (2.12) | −4.24 | (2.09) | 0.7713 | −4.08 | (2.06) | −4.04 | (2.05) | −4.10 | (2.07) | 0.4891 |
| C24:0 | Lignoceric | −1.14 | (0.37) | −1.13 | (0.35) | −1.15 | (0.38) | 0.5647 | −1.20 | (0.44) | −1.17 | (0.42) | −1.22 | (0.44) | 0.5063 |
| MUFAs | 3.36 | (0.15) | 3.36 | (0.15) | −1.16 | (0.12) | 0.5856 | 3.40 | (0.13) | 3.41 | (0.13) | 3.40 | (0.13) | 0.8740 | |
| C12:1n-1 | −2.12 | (0.38) | −2.12 | (0.35) | −2.11 | (0.39) | 0.5121 | −2.08 | (0.37) | −2.07 | (0.34) | −2.09 | (0.39) | 0.9324 | |
| C14:1n-5 | Myristoleic | 0.53 | (0.27) | 0.52 | (0.26 | 0.54 | (0.27) | 0.2286 | 0.57 | (0.28) | 0.57 | (0.27) | 0.57 | (0.28) | 0.7140 |
| C16:1n-7 | Palmitoleic | 2.64 | (0.29) | 2.64 | (0.29) | 2.63 | (0.30) | 0.9015 | 2.60 | (0.28) | 2.59 | (0.27) | 2.61 | (0.28) | 0.4285 |
| C18:1n-9 | Vaccenic | 5.30 | (0.19) | 5.29 | (0.21 | 5.30 | (0.18) | 0.8530 | 5.34 | (0.17) | 5.34 | (0.17) | 5.34 | (0.17) | 0.9269 |
| C18:1n-7 | Oleic | 2.27 | (0.22) | 2.27 | (0.22) | 2.27 | (0.21) | 0.6890 | 2.24 | (0.25) | 2.24 | (0.21) | 2.24 | (0.27) | 0.6195 |
| C20:1n-9 | Eicosenoic | 0.90 | (0.21) | 0.90 | (0.22) | 0.89 | (0.21) | 0.7753 | 0.83 | (0.23) | 0.84 | (0.24) | 0.83 | (0.22) | 0.5270 |
| C22:1n-9 | Erucic | −0.83 | (0.25) | −0.83 | (0.26) | −0.83 | (0.24) | 0.7583 | −0.92 | (0.28) | −0.91 | (0.29) | −0.93 | (0.27) | 0.2574 |
| C24:1n-9 | Nervonic | −1.16 | (0.59) | −1.17 | (0.61) | −1.16 | (0.58) | 0.9745 | −1.26 | (0.52) | −1.26 | (0.52) | −1.26 | (0.51) | 0.7422 |
| Trans-FAs | −1.13 | (0.57) | −1.11 | (0.53) | 3.47 | (0.13) | 0.7707 | −1.02 | (0.56) | −0.98 | (0.58) | −1.04 | (0.54) | 0.8431 | |
| C14:1n-5t | Myristelaidic | −4.24 | (0.58) | −4.27 | (0.62) | −4.22 | (0.55) | 0.3249 | −4.20 | (0.57) | −4.19 | (0.53) | −4.21 | (0.59) | 0.9244 |
| C15:1n-5t | −4.16 | (0.50) | −4.15 | (0.39) | −4.17 | (0.55) | 0.7865 | −4.15 | (0.50) | −4.16 | (0.48) | −4.15 | (0.52) | 0.8666 | |
| C16:1n-7t | −1.97 | (0.56) | −1.99 | (0.62) | −1.96 | (0.52) | 0.9266 | −1.98 | (0.56) | −1.97 | (0.56) | −1.98 | (0.57) | 0.7485 | |
| T18:1 | 0.72 | (0.88) | 0.74 | (0.84) | 0.70 | (0.91) | 0.6301 | 0.84 | (0.81) | 0.88 | (0.78) | 0.82 | (0.83) | 0.4712 | |
| C18:2n6-tt | Linolelaidic | −2.37 | (1.51) | −2.28 | (1.45) | −2.42 | (1.55) | 0.5086 | −2.23 | (1.50) | −2.12 | (1.39) | −2.29 | (1.56) | 0.4403 |
| BCFAs | −1.81 | (0.34) | −1.83 | (0.34) | 2.09 | (0.24) | 0.6450 | −1.72 | (0.33) | −1.72 | (0.32) | −1.72 | (0.33) | 0.3358 | |
| C15ai | Anteisopentadecylic | −0.43 | (0.37) | −0.45 | (0.33) | −0.41 | (0.38) | 0.3447 | −0.34 | (0.35) | −0.34 | (0.35) | −0.34 | (0.36) | 0.7713 |
| C16i | Isopalmitic | −0.70 | (0.28) | −0.72 | (0.27) | −0.70 | (0.28) | 0.4236 | −0.64 | (0.33) | −0.63 | (0.27) | −0.64 | (0.36) | 0.7147 |
| C18i | Anteisopentadecylic | −1.89 | (0.24) | −1.92 | (0.25) | −1.88 | (0.24) | 0.0791 | −1.83 | (0.23) | −1.84 | (0.23) | −1.82 | (0.22) | 0.3359 |
| PUFAs | 2.21 | (0.23) | 2.20 | (0.24) | 3.36 | (0.15) | 0.3504 | 2.26 | (0.22) | 2.24 | (0.20) | 2.27 | (0.23) | 0.8778 | |
| C18:2n6 | Linoleic | 4.03 | (0.29) | 4.01 | (0.32) | 4.04 | (0.28) | 0.2269 | 4.09 | (0.28) | 4.06 | (0.25) | 4.11 | (0.29) | 0.1221 |
| C18:3n6 | γ-linolenic | −0.41 | (0.36) | −0.42 | (0.41) | −0.41 | (0.33) | 0.9401 | −0.56 | (0.35) | −0.59 | (0.36) | −0.54 | (0.34) | 0.0686 |
| C20:2n-6 | Eicosadienoic | 0.40 | (0.24) | 0.38 | (0.24) | 0.41 | (0.23) | 0.2493 | 0.25 | (0.24) | 0.23 | (0.23) | 0.26 | (0.24) | 0.1938 |
| C20:3n-6 | Dihomo-γ-linolenic | 0.68 | (0.25) | 0.68 | (0.26) | 0.68 | (0.25) | 0.9997 | 0.41 | (0.24) | 0.38 | (0.23) | 0.43 | (0.24) | 0.0136 |
| C20:4n-6 | Arachidonic | 0.86 | (0.22) | 0.87 | (0.24) | 0.86 | (0.22) | 0.6266 | 0.82 | (0.23) | 0.80 | (0.23) | 0.84 | (0.22) | 0.0359 |
| C22:2n-6 | Docosadienoic | −1.95 | (0.62) | −1.91 | (0.36) | −1.97 | (0.73) | 0.8907 | −2.32 | (1.00) | −2.33 | (0.95) | −2.32 | (1.03) | 0.4210 |
| C22:4n-6 | Adrenic | −0.79 | (0.36) | −0.77 | (0.28) | −0.81 | (0.40) | 0.1586 | −0.84 | (0.34) | −0.86 | (0.44) | −0.82 | (0.26) | 0.4940 |
| C22:5n-6 | Osbond | −1.53 | (0.36) | −1.51 | (0.31) | −1.54 | (0.38) | 0.3628 | −1.67 | (0.38) | −1.72 | (0.38) | −1.64 | (0.38) | 0.0134 |
| Σn-6 PUFA | 2.08 | (0.25) | 2.06 | (0.26) | 2.07 | (0.25) | 0.4362 | 2.13 | (0.24) | 2.11 | (0.21) | 2.14 | (0.25) | 0.1709 | |
| Σn-6 LCPUFA | −0.17 | (0.16) | −0.17 | (0.16) | −0.85 | (0.24) | 0.9706 | −0.30 | (0.15) | −0.31 | (0.15) | −0.29 | (0.16) | 0.3544 | |
| C18:3n-3 | α-linoleic | 1.60 | (0.38) | 1.59 | (0.41) | 1.61 | (0.37) | 0.3960 | 1.69 | (0.38) | 1.69 | (0.37) | 1.69 | (0.39) | 0.6836 |
| C20:3n-3 | Dihomo-α-linoleic | −1.44 | (0.36) | −1.44 | (0.31) | −1.44 | (0.39) | 0.4449 | −1.59 | (0.47) | −1.59 | (0.52) | −1.59 | (0.45) | 0.7333 |
| C20:4n-3 | −0.71 | (0.32) | −0.70 | (0.32) | −0.71 | (0.32) | 0.7514 | −1.05 | (0.32) | −1.07 | (0.33) | −1.04 | (0.31) | 0.5243 | |
| C20:5n-3 | Eicosapentaenoic | −0.98 | (0.36) | −0.95 | (0.37) | −0.99 | (0.36) | 0.3504 | −1.01 | (0.39) | −1.02 | (0.39) | −1.01 | (0.39) | 0.8069 |
| C22:5n-3 | Docosapentanoic | −0.18 | (0.22) | −0.17 | (0.23) | −0.19 | (0.22) | 0.6234 | −0.15 | (0.22) | −0.16 | (0.23) | −0.14 | (0.21) | 0.2787 |
| C22:6n-3 | Docosahexaenoic | 0.35 | (0.39) | 0.34 | (0.42) | 0.35 | (0.38) | 0.9592 | 0.20 | (0.44) | 0.18 | (0.44) | 0.21 | (0.44) | 0.8271 |
| Σn-3 PUFAs | 0.07 | (0.27) | 0.07 | (0.29) | −1.14 | (0.58) | 0.9518 | 0.09 | (0.28) | 0.10 | (0.27) | 0.09 | (0.29) | 0.4032 | |
| Σn-3 LCPUFAs | −0.84 | (0.25) | −0.84 | (0.25) | 2.22 | (0.22) | 0.9518 | −0.94 | (0.27) | −0.95 | (0.28) | −0.94 | (0.26) | 0.4032 | |
| Met Index | Metabolic Index | 1.16 | (0.14) | 1.16 | (0.16) | −0.17 | (0.16) | 0.2407 | 1.16 | (0.14) | 1.17 | (0.15) | 1.16 | (0.13) | 0.2585 |
| D6D | D6D activity | −1.16 | (0.14) | −1.16 | (0.16) | −1.79 | (0.35) | 0.5772 | −1.16 | (0.14) | −1.17 | (0.15) | −1.16 | (0.13) | 0.6815 |
FA—fatty acid; SFAs—saturated fatty acids; MUFAs—monounsaturated fatty acids; BCFAs—branched chain fatty acids; PUFAs—polyunsaturated fatty acids; D6D—delta-6-desaturase. p—p values derived from the Wilcoxon signed-rank test comparing fatty acid concentrations between allergic and non-allergic groups at each time point. Bonferroni-adjusted level of statistical significance is α = 0.05/56 = 0.0009.
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Siziba, L.P.; Lorenz, L.; Stahl, B.; Mank, M.; Marosvölgyi, T.; Decsi, T.; Rothenbacher, D.; Genuneit, J. Human Milk Fatty Acid Composition of Allergic and Non-Allergic Mothers: The Ulm SPATZ Health Study. Nutrients 2020, 12, 1740. https://doi.org/10.3390/nu12061740
AMA Style
Siziba LP, Lorenz L, Stahl B, Mank M, Marosvölgyi T, Decsi T, Rothenbacher D, Genuneit J. Human Milk Fatty Acid Composition of Allergic and Non-Allergic Mothers: The Ulm SPATZ Health Study. Nutrients. 2020; 12(6):1740. https://doi.org/10.3390/nu12061740
Chicago/Turabian StyleSiziba, Linda P., Leonie Lorenz, Bernd Stahl, Marko Mank, Tamas Marosvölgyi, Tamas Decsi, Dietrich Rothenbacher, and Jon Genuneit. 2020. "Human Milk Fatty Acid Composition of Allergic and Non-Allergic Mothers: The Ulm SPATZ Health Study" Nutrients 12, no. 6: 1740. https://doi.org/10.3390/nu12061740
APA StyleSiziba, L. P., Lorenz, L., Stahl, B., Mank, M., Marosvölgyi, T., Decsi, T., Rothenbacher, D., & Genuneit, J. (2020). Human Milk Fatty Acid Composition of Allergic and Non-Allergic Mothers: The Ulm SPATZ Health Study. Nutrients, 12(6), 1740. https://doi.org/10.3390/nu12061740
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