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Associations between breast milk intake volume, macronutrient intake and infant growth in a longitudinal birth cohort: the Cambridge Baby Growth and Breastfeeding Study (CBGS-BF)

Published online by Cambridge University Press:  19 October 2022

Laurentya Olga
Affiliation:
Department of Paediatrics, University of Cambridge, Cambridge, UK
Jacques Vervoort
Affiliation:
Department of Agrotechnology and Food Sciences, Wageningen University, Wageningen, the Netherlands
Janna A. van Diepen
Affiliation:
Medical and Scientific Affairs, Reckitt/Mead Johnson Nutrition Institute, Nijmegen, the Netherlands; Evansville, IN, USA
Gabriele Gross
Affiliation:
Medical and Scientific Affairs, Reckitt/Mead Johnson Nutrition Institute, Nijmegen, the Netherlands; Evansville, IN, USA
Clive J. Petry
Affiliation:
Department of Paediatrics, University of Cambridge, Cambridge, UK
Philippa M. Prentice
Affiliation:
Department of Paediatrics, University of Cambridge, Cambridge, UK
Maciej Chichlowski
Affiliation:
Medical and Scientific Affairs, Reckitt/Mead Johnson Nutrition Institute, Nijmegen, the Netherlands; Evansville, IN, USA
Eric A. F. van Tol
Affiliation:
Medical and Scientific Affairs, Reckitt/Mead Johnson Nutrition Institute, Nijmegen, the Netherlands; Evansville, IN, USA
Ieuan A. Hughes
Affiliation:
Department of Paediatrics, University of Cambridge, Cambridge, UK
David B. Dunger
Affiliation:
Department of Paediatrics, University of Cambridge, Cambridge, UK Institute of Metabolic Science, University of Cambridge, Cambridge, UK
Ken K. Ong*
Affiliation:
Department of Paediatrics, University of Cambridge, Cambridge, UK Institute of Metabolic Science, University of Cambridge, Cambridge, UK MRC Epidemiology Unit, Wellcome Trust-MRC Institute of Metabolic Science, NIHR Cambridge Comprehensive Biomedical Research Centre, Cambridge Biomedical Campus, University of Cambridge, Cambridge, CB2 0QQ, UK
*
*Corresponding author: Dr K. K. Ong, fax +44 1223 330316, email [email protected]
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Abstract

Growth patterns of breastfed infants show substantial inter-individual differences, partly influenced by breast milk (BM) nutritional composition. However, BM nutritional composition does not accurately indicate BM nutrient intakes. This study aimed to examine the associations between both BM intake volumes and macronutrient intakes with infant growth. Mother–infant dyads (n 94) were recruited into the Cambridge Baby Growth and Breastfeeding Study (CBGS-BF) from a single maternity hospital at birth; all infants received exclusive breast-feeding (EBF) for at least 6 weeks. Infant weight, length and skinfolds thicknesses (adiposity) were repeatedly measured from birth to 12 months. Post-feed BM samples were collected at 6 weeks to measure TAG (fat), lactose (carbohydrate) (both by 1H-NMR) and protein concentrations (Dumas method). BM intake volume was estimated from seventy infants between 4 and 6 weeks using dose-to-the-mother deuterium oxide (2H2O) turnover. In the full cohort and among sixty infants who received EBF for 3+ months, higher BM intake at 6 weeks was associated with initial faster growth between 0 and 6 weeks (β + se 3·58 + 0·47 for weight and 4·53 + 0·6 for adiposity gains, both P < 0·0001) but subsequent slower growth between 3 and 12 months (β + se − 2·27 + 0·7 for weight and −2·65 + 0·69 for adiposity gains, both P < 0·005). BM carbohydrate and protein intakes at 4–6 weeks were positively associated with early (0–6 weeks) but tended to be negatively related with later (3–12 months) adiposity gains, while BM fat intake showed no association, suggesting that carbohydrate and protein intakes may have more functional relevance to later infant growth and adiposity.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

Early postnatal nutrition strongly affects or mediates the link between early-life and long-term health outcomes(Reference Lanigan and Singhal1). With regard to this, breast-feeding (BF) has been associated with desirable infancy growth patterns(Reference Ziegler2) and reduced future metabolic risks(Reference Bergmann, Bergmann and Von Kries3).

Compared with infants receiving formula, breastfed infants have been described to display remarkably different growth trajectories(Reference Ong, Preece and Emmett4), with faster weight and length gains in the first months(Reference Ong, Preece and Emmett4Reference Küpers, L’Abée and Bocca6), an earlier infant BMI peak(Reference Jensen, Ritz and Ejlerskov7), and slower growth gains up to 2–3 years(Reference Ong, Preece and Emmett4Reference Küpers, L’Abée and Bocca6). On the contrary, infants receiving formula have slower beginning growth gains but the pace constantly increases, resulting in higher weight (both weight-for-age and weight-for-length Z-scores) compared with breastfed infants observed as early as 6 months of age(Reference Küpers, L’Abée and Bocca6,Reference Dewey, Heinig and Nommsen8) . Besides being heavier, infants receiving formula are characterised by larger skinfold thicknesses and higher body fat percentage from 9 months through 2 years of age(Reference Dewey, Heinig and Nommsen8,Reference Gale, Logan and Santhakumaran9) . Moreover, the growth rate moderating effect provided by BF (especially prolonged and exclusive BF) appears to persist(Reference Dewey, Heinig and Nommsen8Reference Johnson, Van Jaarsveld and Llewellyn10) and thus is associated with protection against childhood overweight/obesity(Reference Bergmann, Bergmann and Von Kries3), particularly among those with higher risks, for example, born small/large for gestational age with rapid weight gain in early infancy(Reference Ejlerskov, Christensen and Ritz11).

This overall growth trajectory of breastfed infants may be influenced by the composition of human breast milk (BM)(Reference Prentice, Ong and Schoemaker12). Several studies have highlighted the potential importance of macronutrient composition in BM for weight and adiposity gains during infancy(Reference Prentice, Ong and Schoemaker12Reference Ballard and Morrow14). However, these strictly observational studies relied mainly on maternal recall and were confounded by many factors, including feeding behaviours, weaning/complementary feeding and maternal/pregnancy/infant co-morbidities(Reference Adair15). Furthermore, the concentration of nutrients in BM does not reflect the absolute nutrient amounts consumed by infants. Quantification of the nutrients consumed from BM would therefore provide a better mechanistic link between BF and infancy growth and adiposity.

In this study, we aimed to measure macronutrient intake from BM by quantifying carbohydrate, fat and protein concentrations from BM combined with estimating the volume of BM consumed by infants in a strictly monitored longitudinal UK-based birth cohort. We hypothesised that the amount of BM intake and specific BM composition are associated with weight and adiposity gains during infancy.

Methods

Study design and participants

The Cambridge Baby Growth and Breastfeeding Study (CBGS-BF)(Reference Olga, Petry and van Diepen16) comprises in total ninety-four mother–infant dyads who were consecutively recruited at birth from one maternity hospital in Cambridge, UK (2015–2017). These inclusion criteria were applied: singleton pregnancy, no significant maternal illness (including hypertension and/or diabetes during pregnancy and any other chronic illnesses, or any regular medication use), full-term vaginal delivery, maternal pre-pregnancy BMI within the healthy range(17) and intention to exclusive breast-feeding (EBF) for at least 6 weeks. The protocol of the study has been published elsewhere(Reference Olga, Petry and van Diepen16). Given the strict inclusion criteria of the study, the sample size was determined by the feasibility of recruitment with a minimal number of samples of 67, aiming to detect a minimal effect size of 0·2 with 90 % power at the 5 % level.

The total numbers of subjects with BM intake volume (main outcome thus being the analytic sample) and BM macronutrient concentrations measurements were 70 and 59, respectively. In total, there were forty-seven subjects with complete measurements (online Supplementary Table 1).

This study was conducted in compliance with the Declaration of Helsinki. All procedures involving research participants in the study were approved by the National Research Ethics Service Cambridgeshire 2 Research Ethics Committee (reference number 11/EE/0068. Written informed consent was obtained from all mothers in the study, for themselves and on behalf of their infants.

Anthropometry

Trained paediatric research nurses measured infant weight, length and skinfold thickness at four sites (triceps, subscapular, flank and quadriceps). Following UK guidelines, weight, length and BMI values were converted to sex- and age-adjusted standard deviation scores (SDS) using the British 1990 growth reference at birth (LMS Growth(Reference Pan and Cole18)) and subsequently using WHO International Growth Standard (‘anthro’ package-WHO(Reference Schumacher, Borghi and Polonsky19)). Internal SDS were calculated for each skinfold thickness site by employing the residuals from linear regression models, adjusted for sex and age, and then the mean skinfolds SDS was calculated as measures of infant adiposity.

Anthropometry data quality control was maintained by involving the same paediatric research nurses throughout the study, regular machine calibration, and periodical personnel training and measurement review/monitoring conducted by an anthropometry specialist in the unit.

Breast milk intake volume measurement

The volume of BM consumed by each infant at 4–6 weeks of age was measured using the dose-to-the-mother deuterium-oxide (2H2O) turnover technique, and the detailed methodology has been described previously(Reference Olga, Petry and van Diepen16,Reference Haisma, Coward and Albernaz20) .

In brief, when infants were 4 weeks old, baseline urine samples were taken from both mothers and infants. The next day, mothers ingested 50 g of deuterium-enriched (tracer) water, which was then incorporated into BM and passed to the infants during BF. Repeated urine samples were collected from both mothers and infants over the following 2 weeks. To collect urine samples from infants, cotton wool was placed into the nappies and checked every hour. Cotton wool that was saturated with urine was transferred to a syringe barrel, and urine was extracted using the syringe plunger.

2H is a non-radioactive, naturally occurring isotope. In this study, 2H enrichment in the urine samples was measured using isotope-ratio MS. The amount of BM intake volume was estimated by formulating a curve of isotope enrichment transfer between each mother and her infant(Reference Olga, Petry and van Diepen16,Reference Haisma, Coward and Albernaz20) .

Breast milk collection and macronutrient assays

Mothers were asked to hand or pump express their BM samples after feeding their infants at each visit from birth until 12 months of infant age (if mothers were still BF)(Reference Olga, Petry and van Diepen16). Expression was done from the same breast last used to feed the infants. Individual samples were kept frozen at -70°C until processed for further analyses at a single time point. Of note, as reported in the literature, post-feed samples may contain higher fat(Reference Khan, Hepworth and Prime21) and total protein(Reference van Sadelhoff, Mastorakou and Weenen22) and therefore may not be able to represent the exact estimates of macronutrient intakes in BM.

At the time of assay, individual BM samples were defrosted and thoroughly mixed. From these homogenised BM samples, lactose (as the predominant BM carbohydrate) and TAG (as the predominant BM fat) concentrations were measured by 1H-NMR(Reference Prentice, Ong and Schoemaker12,Reference Ballard and Morrow14) . Total nitrogen was measured by the Dumas method to calculate BM protein concentration(Reference Dumas23). These BM macronutrient assays were based on our previous work with CV of 0·3–5·8 % for lipids and 0·4–4·7 % for polar metabolites (e.g. lactose). These values have been reported in detail in our previous publications(Reference Prentice, Ong and Schoemaker12).

Since BM intake volume is not significantly different between the age of 1 and 6 months(Reference Kent, Mitoulas and Cregan24), we used the single BM intake volume measurement at the age of 6 weeks as an estimate for other time points, that is, 6 weeks, 3 months and 6 months to enable longitudinal BM macronutrient intake analyses.

Calculations and statistical analyses

Atwater conversions were used to calculate the metabolisable energy concentration of BM, taking energy concentrations of 4, 9 and 4 kcal/g for lactose, fat and protein, respectively(Reference Southgate25). BM macronutrient intake (g/d) was calculated as the product of each macronutrient concentration (g/100 ml) at the age of 6 weeks – 6 months and BM intake volume (l/d) at 6 weeks as proxy for all other time points.

Continuous variables were summarised as mean and standard deviation or median (interquartile range), and categorical variables as number (%). The analytic sample (n 70) did not have any missing anthropometry or maternal/perinatal data. Subjects without BM macronutrient concentrations measured were not included in the relevant analyses (pairwise deletion method to handle missing data).

Multiple linear regression models were run with BM intake volume and BM macronutrient intakes as predictors and infant growth gains as outcomes. Prior to this, both BM macronutrient concentrations and intakes were found unrelated to maternal age, ethnicity, pre-pregnancy BMI, height and parity from correlation analyses; therefore, these factors were not included as covariates in the regression models. Taking these preliminary analyses into account and using a data-agnostic approach while also considering biological plausibility, those regression models were further adjusted for infant sex, birth weight SDS, GA, postnatal age at visit and EBF status. To demonstrate robust associations between BM macronutrient intakes and subsequent infant growth outcomes, these regression analyses were performed only among infants who received EBF for 3+ months (n 40, online Supplementary Table 1).

To capitalise on the longitudinal growth and macronutrient intakes data with appropriate handling of missing values, linear mixed-effects models were used to examine the associations between growth and body composition parameters, that is, weight, height, BMI and mean skinfolds, with each BM macronutrient intake, that is, carbohydrate, protein and fat. The models were adjusted for the same set of covariates as the multiple linear regressions. Due to non-linear relationships between growth and age (as reported previously(Reference Prentice, Olga and Petry26,Reference Olga, van Diepen and Gross27) ), time was modelled using linear splines with one knot at the age of 3 months, resulting in two periods: 0–3 and 3–12 months. Models were fitted to the data by restricted maximum likelihood.

All analyses were performed using SPSS version 25 (IBM Corp.) and R version 3.6.1 (R Foundation for Statistical Computing). P < 0·05 indicated statistical significance in descriptive statistics. Bonferroni corrections were used to take into account the multiple comparisons, assuming 2X broad growth phenotypes (adiposity and length) and 3X time periods for multiple linear regression models (i.e. P < 0·05/6 = 0·0083) or 2X time periods for linear mixed-effects models (i.e. P < 0·05/4 = 0·0125).

Results

All seventy infants (analytic sample) were EBF for at least 6 weeks. After that, ten commenced mixed feeding with the introduction of formula between 6 and 12 weeks, while the remaining sixty (86 %) were EBF for 3+ months, of which thirty-eight were EBF for the first 3–6 months and twenty-two infants were EBF for 6+ months. Their characteristics are summarised in Table 1. All mothers had BMI values that were within the healthy range(17) (mean + sd: 22·54 + 2·71). Almost 40 % were primiparous and most (94 %) were of White/European ethnicity. Their baseline demographics did not differ from the whole study population (n 94; online Supplementary Table 2).

Table 1. Baseline characteristics of the analytic study sample (n 70)

SDS, standard deviation scores.

Values are mean and sd or n (%) as appropriate.

SDS values at birth are based on British 1990 growth reference and at other time points are based on WHO International Growth Standard.

Breast milk intake volumes

The values of BM intake volume measured at 4–6 weeks ranged from 0·45 to 1·26 (mean + sd 0·78 + 0·16) l/d and were higher in male v. female infants (0·81 + 0·17 v. 0·73 + 0·14, respectively, P = 0·044). When corrected for body size, mean and standard deviation of BM intake volume in this study is 0·15 + 0·02l/kg body weight/d. Compared with infants who continued EBF for 6–12 weeks, EBF infants for 3+ months consumed higher volumes of BM daily (0·8 + 0·16 v. 0·66 + 0·13, P = 0·017).

Infants with higher BM intake volumes at 4–6 weeks showed faster weight (adjusted Pearson’s R correlation coefficient = 0·71, P < 0·0001; Fig. 1), height and adiposity gains between birth and age 6 weeks (while all infants received EBF). Conversely, subsequent growth displayed the opposite correlations: infants with higher BM intake volumes at 4–6 weeks showed slower weight and adiposity gains between 3 and 12 months of age (online Supplementary Table 3). Similar associations were identified among the sixty infants who were EBF for 3+ months: higher breast milk intake volumes at 4–6 weeks predicted slower weight gain between 3 and 12 months (Table 2).

Fig. 1. Correlation between BM intake volume at 4–6 weeks and infant weight gain from 0 to 6 weeks. Two-tailed partial correlation coefficient is presented, adjusted for infant sex and GA. BM, breast milk; GA, gestational age; SDS, standard deviation scores.

Table 2. Associations between BM macronutrient intake at 6 weeks with infant growth and adiposity

BM, breast milk; EBF, exclusive breast-feeding; SDS, standard deviation scores; β + se, unstandardised regression coefficient + standard error.

* Statistical significance after Bonferroni correction for multiple comparisons (P < 0·0083).

The models include only infants with EBF 3+ months (n 40 for macronutrients models and 60 for BM intake volume models). All multiple linear regression models were adjusted for infant sex, birth weight SDS, gestational age, postnatal age at visit, EBF status at 6 months and other BM macronutrient concentrations at 6 weeks (for macronutrients models only). Associations at P < 0·05 are indicated in bold.

BM macronutrient concentrations and intakes

Table 3 shows BM macronutrient concentration at 6 weeks (expressed as calories/100 ml and percentage of total calorie concentration (%TCC)). Compared with data from an earlier CBGS cohort(Reference Prentice, Ong and Schoemaker12), the current BM samples contained significantly lower lactose, higher TAG and similar protein concentrations.

Table 3. BM macronutrient concentrations and intakes at 6 weeks

BM, breast milk; CBGS-BF, the Cambridge Baby Growth and Breastfeeding Study; % TCC, % total calorie content (calculated as macronutrient energy/total energy concentration).

* The comparisons of carbohydrate and fat concentrations between current and previous studies reached significance (P < 0·05).

** BM intake volume was not available in the previous CBGS.

BM protein concentration was negatively associated with BM intake volume (Table 4). In addition, protein concentration was positively correlated with fat concentration, and both protein and fat were positively correlated with BM TCC.

Table 4. Correlations between BM intake volume (measured between 4–6 weeks) and macronutrient concentrations (measured at 6 weeks)

BM, breast milk.

Pearson’s R correlation coefficients and their corresponding P values are presented.

Statistically significant correlations (P < 0·05) are highlighted in bold.

BM macronutrient intakes and infant growth over time

The associations between BM intake volume as well as macronutrient intakes and infant growth between 0 and 12 months were evaluated.

Separately at each time point, carbohydrate and protein intakes at 4–6 weeks were positively correlated with all early growth parameters, that is, at 6 weeks and 3 months (online Supplementary Table 4). In linear regression models, carbohydrate and protein intakes were positively associated with early gains in weight, BMI and adiposity between 0 and 6 weeks but tended to show inversely associations with later gains in weight, BMI and adiposity from 3 to 12 months, although only protein and change in skinfolds reached Bonferroni significance (Table 2). Linear mixed-effects models confirmed the positive associations between carbohydrate and protein intakes with early gains in weight between 0 and 3 months and showed a negative association between carbohydrate intakes with later weight between 3 and 12 months (Table 5).

Table 5. Longitudinal associations between BM macronutrient intake and infant growth and adiposity

BM, breast milk; SDS, standard deviation scores, SF, skinfolds; GA, gestational age; EBF, exclusive breast-feeding.

* Statistical significance after Bonferroni correction for multiple comparisons (P < 0·0125).

Fixed effect estimates +se are displayed.

Analyses are based on linear mixed-effect models, adjusted for infant sex, birth weight SDS, GA, postnatal age at visit, EBF status at 3 months and other BM macronutrient concentrations. Smoothing splines were added to the models with knot at 3 months. Associations at P < 0·05 are indicated in bold.

Discussion

The objective of this study was to investigate the associations between BM macronutrient intakes and infant growth/adiposity and therefore require a well-controlled mother–infant dyad study population. In this cohort, all infants were vaginally born of healthy mothers with BMI in the healthy range and were EBF for the first 6 weeks. The prevalence of EBF at 3 months in this cohort (86 %) was much higher than the UK national prevalence in 2010 (17 %)(Reference McAndrew, Thompson and Fellows28).

Infant sex and EBF duration influenced BM intake volumes, with males and longer EBF duration associated with higher BM intake volumes at 6 weeks of age. The effect of infant sex on BM intake volume reported in this study (male infants consumed 80 g more BM daily) was similar to a multinational study conducted by Da Costa et al. with 50 g/d more BM consumed by males than females(Reference Da Costa, Haisma and Wells29).

Compared with previous data from an earlier CBGS cohort(Reference Prentice, Ong and Schoemaker12) and a published overview by Ballard and Morrow(Reference Ballard and Morrow14), BM in this study contained lower lactose, higher fat, but comparable protein concentrations (term BM macronutrient concentrations according to the overview were(Reference Ballard and Morrow14): 0·9–1·2 g/100 ml protein, 3·2–3·6 g/100 ml fat and 6·7–7·8 g/100 ml lactose). BM TCC was similar to previous reports: in this study BM at 6 weeks contained 65·0 + 19·5 kcal TCC/100 ml compared with values in the published overview (65–70 kcal/100 ml BM(Reference Ballard and Morrow14)). Lower lactose and higher fat BM contents observed in this study might be due to differences in BM sampling at distinct time points as compared with the pooled sampling over a 2-week period in the previous CBGS study(Reference Prentice, Ong and Schoemaker12).

It might be expected that higher BM intake volumes in EBF infants would be positively related to growth rates. Indeed, we observed that shortly after birth, infants with higher BM intake volumes at 4–6 weeks displayed faster gains in all growth parameters. However, at later time points, weight and adiposity gains were slower in these infants (Fig. 2, online Supplementary Table 2, Supplementary Fig. 1). This growth pattern is in accordance with the characteristics of breastfed infants: rapid growth gains during early infancy but slower in later months(Reference Dewey, Heinig and Nommsen8). This slower growth pattern in later infancy is speculated to be protective against obesity risk in adolescence and adulthood(Reference Mameli, Mazzantini and Zuccotti30). The main objective of this study was to investigate which macronutrients of BM were related to this typical growth pattern of breastfed infants.

Fig. 2. Correlation between carbohydrate intake at 6 weeks and infant weight gain. SDS, standard deviation scores.

Of note, of all covariates included in the models, birth weight and gestational age were the most significant contributors to early weight gain 0–6 weeks (% variance explained 9 % and 3 %, respectively). As shown in Supplementary Fig. 1, the highest tertile BM intake group were born heavier compared with the other groups.

In our previous CBGS cohort, BM fat and carbohydrate concentrations were associated with changes in infancy weight and adiposity up to age 12 months; BM protein concentration was positively correlated with 12-month BMI(Reference Prentice, Ong and Schoemaker12). However, data on milk intakes were not available in that cohort. In contrast, the current study design, including BM intake volume measurement, allowed for exploration of the effects of macronutrient intakes from BM on infancy growth and adiposity. Positive associations were identified between BM carbohydrate and protein intakes with weight and BMI during early infancy period, but negative trends were seen with later outcomes. However, no associations were found between BM fat intake and infant growth.

The positive associations between BM carbohydrate and protein intakes with earlier infant growth gains found in this study are in line with the associations of the concentrations of those macronutrients with early growth that have been reported in the existing literature(Reference Prentice, Ong and Schoemaker12,Reference Butte, Wong and Hopkinson31) . The excess of BM carbohydrate intake could presumably be stored as glycogen and fat and therefore result in greater growth and increased adiposity(Reference Maljaars, Romeyn and Haddeman32). To the best of our knowledge, the evidence linking protein intakes from BM with infant growth is still scarce, unlike studies involving formula. High protein intakes from traditional formula has been linked with rapid weight gain in comparison with both breastfed(Reference Haschke, Grathwohl and Detzel13) and infants fed with low-protein formula(Reference Inostroza, Haschke and Steenhout33). In this study, the independent positive association between BM protein intake with early infant growth was also not confounded by BM intake volume, since BM protein concentrations were inversely correlated with BM intake volume (Table 4), which is also consistent with previous observations(Reference Nommsen, Lovelady and Heinig34,Reference Czosnykowska-Łukacka, Królak-Olejnik and Orczyk-Pawiłowicz35) . In the Davis Area Research on Lactation, Infant Nutrition and Growth (DARLING) study, milk protein concentration was negatively correlated with milk volume at 6 and 9 months, while milk lactose was positively correlated(Reference Nommsen, Lovelady and Heinig34). Similar to our findings, the milk energy density in that study was highly correlated with lipid concentration. Furthermore, the robust positive association between protein intakes and early postnatal growth parameters that persisted after Bonferroni correction for multiple comparisons are consistent with observations linking high protein intake from formula with rapid weight gain(Reference Haschke, Grathwohl and Detzel13), possibly by promoting higher levels of insulin-like growth factor 1. Animal and human studies have reported that high protein intakes increase insulin-like growth factor 1 secretion and therefore may accelerate gains in both muscle and fat(Reference Hoppe, Mølgaard and Thomsen36,Reference Desclée de Maredsous, Oozeer and Barbillon37) .

Interestingly, inverse associations or trends were also observed between BM carbohydrate intake with later weight and adiposity gains, as well as between BM protein intake with later adiposity gain (Table 2). This might suggest that both macronutrients substantially contribute to the typical growth pattern of breastfed infants.

High intake of protein, especially if sustained in long duration, appears to help reduce food intake, body weight and body adiposity in many well-documented studies(Reference Westerterp-Plantenga, Lemmens and Westerterp38Reference Paddon-Jones, Westman and Mattes40). Therefore, increasing protein intake is also one of the established strategies to lose weight, especially to maximise fat loss while avoiding the detrimental loss of fat-free or muscle mass(Reference Simonson, Boirie and Guillet39). This is because dietary proteins are anabolic dietary compounds as their breakdown predominate over their synthesis(Reference Simonson, Boirie and Guillet39). In addition, proteins are considered to have a greater satiating effect than carbohydrate or fat, because protein intake could induce the release of satiety hormones from gastrointestinal tract, for example, cholecystokinin, peptide YY and glucagon-like peptide 1(Reference Cuenca-Sánchez, Navas-Carrillo and Orenes-Piñero41). All of these could probably explain the mechanism behind the strong inverse relationship between BM protein intake and later skinfold gain between 3 and 12 months in this study.

The lack of associations between BM fat intake with infant growth was unexpected and inconsistent with previous studies which have suggested that greater BM fat content might promote infant satiety and hence may be beneficial in preventing rapid gains in infant weight and adiposity(Reference Kratz, Baars and Guyenet42,Reference Rolland-Cachera, Maillot and Deheeger43) . Further exploration using qualitative analyses of BM fat contents beyond only TAG, for example, BM SCFA composition, may provide a better understanding.

The main strength of this study is the measurement of BM intake volume that enables BM nutrient intakes calculation. There are previous studies investigating BM macronutrient intakes, but they usually estimated BM intake volume via 24-h test weighing (i.e. weighing infants before and after every feed for a 24-h period)(Reference George, Gay and Murray44,Reference Eckart, Peck and Kharbanda45) during EBF period or using the values reported from the literature(Reference George, Gay and Wlodek46). In this study, 2H-labelled water was perceived to provide more precise BM intake volume estimates compared with the other methods. Apart from that, this method is also non-invasive, does not require researcher’s intensive observation during the procedure, should not affect milk production or feeding pattern and is reported to highly correlate with 24-h test weighing(Reference Scanlon, Alexander and Serdula47). As demonstrated here, BM intake volumes and BM nutrient intakes, rather than simply BM concentrations, are important factors contributing to the effects of BF on infant growth and therefore should be considered in future studies. In addition, longitudinal study design and analyses of specific growth periods are crucial to understanding nutrition-related factors affecting infant growth and weight/adiposity gains.

However, we recognise several limitations, especially the use of single milk sample per visit rather than a pooled sampling that can take into account sample variability as demonstrated in our previous study(Reference Prentice, Ong and Schoemaker12). We assume the higher fat and lower lactose concentrations observed in this study were due to distinct time points during sampling. Second, only 31 % of the analytic sample (22 out of 70) continued EBF for at least 6 full months, while the remaining infants experienced substantially reduced exposure of BM before 6 months. This could bias towards the null associations between BM macronutrient intakes and growth that were analysed longitudinally until 12 months of age in this study. Moreover, although serial BM macronutrients were conducted, BM intake volume was only measured at a single point, that is, 6 weeks. Since most of our research participants were of White/European ethnicity, the applicability of the results of this study needs validation in larger and more diverse populations. The small number of subjects, especially those with complete measurements, reduced the power in statistical analyses, and therefore the results require confirmation. Comprehensive dietary evaluations of both mothers during EBF and infants during complementary feeding should also be included in future studies.

In conclusion, BF may affect immediate and subsequent infancy growth, and this effect could be modified by BM intake volumes. BM macronutrient intake, especially lactose and protein, may have functional relevance to infant growth and adiposity.

Acknowledgements

The authors acknowledge the CBGS research nurses Suzanne Smith, Anne-Marie Wardell and Karen Forbes, all the families who contributed to the study, the staff at the National Institute for Health Research (NIHR) Cambridge/Wellcome Trust Clinical Research Facility, the NIHR Cambridge Comprehensive Biomedical Research Centre, the midwives at the Rosie Maternity Hospital, Cambridge, UK, and all laboratory staff at the Department of Paediatrics, University of Cambridge, especially Karen Whitehead and Dianne Wingate. The authors also thank Priya Singh and Michelle Venables (MRC Elsie Widdowson Laboratory) for measuring breast milk intake volume and all laboratory staff at Vervoort’s group, Department of Agrotechnology and Food Sciences, Wageningen University for measuring BM macronutrient concentrations. The authors would also like to thank MH Schoemaker for her involvement during initiation of the study.

The Cambridge Baby Growth-Breastfeeding Study (CBGS-BF) has been supported by Reckitt/Mead Johnson Nutrition, the National Institute for Health Research/Wellcome Trust Clinical Research Facility at Cambridge University Hospitals-NHS Foundation Trust and the NIHR Cambridge Comprehensive Biomedical Research Centre. KKO is supported by the Medical Research Council (Unit programmes: MC_UU_12015/2 and MC_UU_00006/2). The original Cambridge Baby Growth Study (CBGS) and the CBGS Paediatric Research Nurses had been supported by the European Union (QLK4-1999-01422), the World Cancer Research Foundation International (2004/03), the Medical Research Council (7500001180), the NIHR Cambridge Comprehensive Biomedical Research Centre, Newlife – The Charity for Disabled Children (07/20) and Mothercare Foundation (RG54608). The funders of the study had no role in study design, data collection, data analysis, data interpretation or writing of the report. The corresponding author had full access to all the data in the study and had final responsibility for the decision to submit for publication.

JAvD, GG and MJ are current employees of Reckitt/Mead Johnson Nutrition, and EAvT was also an employee of Mead Johnson Nutrition at the time of the study. No other authors declare a conflict of interest.

The authors’ responsibilities were as follows: J. V., J. A. V. D., G. G., P. M. P., M. J., E. A. V. T., C. J. P., I. A. H., D. B. D. and K. K. O. were involved in designing the project; P. M. P. and L. O. were responsible for subject recruitment and sample collection/management; J. V. was responsible for all BM macronutrient measurements; J. V. and L. O. were responsible for data wrangling and manipulation; L. O. performed statistical analyses; J. A. V. D., G. G., C. J. P., D. B. D. and K. K. O. critically reviewed all statistical analyses performed in the manuscript; L. O., J. A. V. D., G. G., D. B. D. and K. K. O. wrote the manuscript; K. K. O. had primary responsibility for final content; and all authors critically revised the manuscript for important intellectual content and read and approved the final manuscript.

Supplementary material

For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S0007114522003178

Footnotes

Deceased

References

Lanigan, J & Singhal, A (2009) Early nutrition and long-term health: a practical approach. Proc Nutr Soc 68, 422429.CrossRefGoogle Scholar
Ziegler, EE (2006) Growth of breast-fed and formula-fed infants. Nestlé Nutr Work Ser Pediatr Progr 58, 5163.CrossRefGoogle ScholarPubMed
Bergmann, KE, Bergmann, RL, Von Kries, R, et al. (2003) Early determinants of childhood overweight and adiposity in a birth cohort study: role of breast-feeding. Int J Obes 27, 162172.CrossRefGoogle Scholar
Ong, KK, Preece, MA, Emmett, PM, et al. (2002) Size at birth and early childhood growth in relation to maternal smoking, parity and infant breast-feeding: longitudinal birth cohort study and analysis. Pediatr Res 52, 863867.CrossRefGoogle ScholarPubMed
Michaelsen, KF (2010) WHO growth standards-should they be implemented as national standards? J Pediatr Gastroenterol Nutr 51, Suppl. 3, 151152.CrossRefGoogle ScholarPubMed
Küpers, LK, L’Abée, C, Bocca, G, et al. (2015) Determinants of weight gain during the first 2 years of life-the GECKO Drenthe birth cohort. PLOS ONE 10, 115.CrossRefGoogle Scholar
Jensen, SM, Ritz, C, Ejlerskov, KT, et al. (2015) Infant BMI peak, breastfeeding, and body composition at age 3 years. Am J Clin Nutr 101, 319325.CrossRefGoogle Scholar
Dewey, KG, Heinig, MJ, Nommsen, LA, et al. (1992) Growth of breast-fed and formula-fed infants from 0 to 18 months: the DARLING study. Pediatrics 89, 10351041.CrossRefGoogle Scholar
Gale, C, Logan, KM, Santhakumaran, S, et al. (2012) Effect of breastfeeding compared with formula feeding on infant body composition: a systematic review and meta-analysis. Am J Clin Nutr 95, 656669.CrossRefGoogle ScholarPubMed
Johnson, L, Van Jaarsveld, CHM, Llewellyn, CH, et al. (2014) Associations between infant feeding and the size, tempo and velocity of infant weight gain: SITAR analysis of the Gemini twin birth cohort. Int J Obes 38, 980987.CrossRefGoogle ScholarPubMed
Ejlerskov, KT, Christensen, LB, Ritz, C, et al. (2015) The impact of early growth patterns and infant feeding on body composition at 3 years of age. Br J Nutr 114, 316327.CrossRefGoogle ScholarPubMed
Prentice, P, Ong, KK, Schoemaker, MH, et al. (2016) Breast milk nutrient content and infancy growth. Acta Paediatr 105, 641647.CrossRefGoogle ScholarPubMed
Haschke, F, Grathwohl, D, Detzel, P, et al. (2016) Postnatal high protein intake can contribute to accelerated weight gain of infants and increased obesity risk. Nestle Nutr Inst Workshop Ser 85, 101109.CrossRefGoogle ScholarPubMed
Ballard, O & Morrow, A (2013) Human milk composition: nutrients and bioactive factors. Pediatr Clin North Am 60, 4974.CrossRefGoogle ScholarPubMed
Adair, LS (2008) Child and adolescent obesity: epidemiology and developmental perspectives. Physiol Behav 94, 816.CrossRefGoogle ScholarPubMed
Olga, L, Petry, CJ, van Diepen, JA, et al. (2021) Extensive study of breast milk and infant growth: protocol of the Cambridge baby growth and breastfeeding study (CBGS-BF). Nutrients 13, 2879.CrossRefGoogle ScholarPubMed
World Health Organization (2010) Body Mass Index – BMI. World Health Organization, Europe Regional Office. https://www.euro.who.int/en/health-topics/disease-prevention/nutrition/a-healthy-lifestyle/body-mass-index-bmi (accessed March 2022).Google Scholar
Pan, H & Cole, T (2012) LMSgrowth, A Microsoft Excel Add-In to Access Growth References Based on the LMS Method. http://www.healthforallchildren.co.uk/ (accessed March 2022).Google Scholar
Schumacher, D, Borghi, E, Polonsky, J, et al. (2021) Computation of the WHO Child Growth Standards: Package “Anthro”. World Health Organization. https://github.com/worldhealthorganization/anthroBugReports (accessed March 2022).Google Scholar
Haisma, H, Coward, WA, Albernaz, E, et al. (2003) Breast milk and energy intake in exclusively, predominantly, and partially breast-fed infants. Eur J Clin Nutr 57, 16331642.CrossRefGoogle ScholarPubMed
Khan, S, Hepworth, AR, Prime, DK, et al. (2013) Variation in fat, lactose, and protein composition in breast milk over 24 h: associations with infant feeding patterns. J Hum Lact 29, 8189.CrossRefGoogle Scholar
van Sadelhoff, JHJ, Mastorakou, D, Weenen, H, et al. (2018) Short communication: differences in levels of free amino acids and total protein in human foremilk and hindmilk. Nutrients 10, 1828.CrossRefGoogle ScholarPubMed
Dumas, J (1831) Procedes de l’analyse organique (Methods of organic analysis). Ann Chim Phys 47, 198205.Google Scholar
Kent, JC, Mitoulas, LR, Cregan, MD, et al. (2006) Volume and frequency of breastfeedings and fat content of breast milk throughout the day. Pediatrics 117, e387e395.CrossRefGoogle ScholarPubMed
Southgate, D (1981) The Relationship between Food Composition and Available Energy. Joint FAO/WHO/UNU Expert Consultation on Energy and Protein Requirements. http://www.fao.org/3/M2847E/M2847E00.htm (accessed March 2022).Google Scholar
Prentice, PM, Olga, L, Petry, CJ, et al. (2019) Reduced size at birth and persisting reductions in adiposity in recent, compared with earlier, cohorts of infants born to mothers with gestational diabetes mellitus. Diabetologia 62, 19771987.CrossRefGoogle ScholarPubMed
Olga, L, van Diepen, JA, Gross, G, et al. (2022) Early weight gain influences duration of breast feeding: prospective cohort study. Arch Dis Child 107, 1034–1037.CrossRefGoogle ScholarPubMed
McAndrew, F, Thompson, J, Fellows, L, et al. (2012) Infant Feeding Survey 2010: Summary. Leeds: NHS Digital-Health and Social Care Information Centre.Google Scholar
Da Costa, THM, Haisma, H, Wells, JCK, et al. (2010) How much human milk do infants consume? Data from 12 countries using a standardized stable isotope methodology. J Nutr 140, 22272232.CrossRefGoogle ScholarPubMed
Mameli, C, Mazzantini, S & Zuccotti, GV (2016) Nutrition in the first 1000 d: the origin of childhood obesity. Int J Environ Res Public Health 13, 19.CrossRefGoogle Scholar
Butte, NF, Wong, WW, Hopkinson, JM, et al. (2000) Infant feeding mode affects early growth and body composition. Pediatrics 106, 13551366.CrossRefGoogle ScholarPubMed
Maljaars, J, Romeyn, EA, Haddeman, E, et al. (2009) Effect of fat saturation on satiety, hormone release, and food intake. Am J Clin Nutr 89, 10191024.CrossRefGoogle ScholarPubMed
Inostroza, J, Haschke, F, Steenhout, P, et al. (2014) Low-protein formula slows weight gain in infants of overweight mothers. JPGN 59, 7077.Google ScholarPubMed
Nommsen, L, Lovelady, C, Heinig, MJ, et al. (1991) Determinants of energy, protein, lipid, and lactose concentrations in human milk during the first 12 months of lactation: the DARLING study. Am J Clin Nutr 53, 457465.CrossRefGoogle ScholarPubMed
Czosnykowska-Łukacka, M, Królak-Olejnik, B & Orczyk-Pawiłowicz, M (2018) Breast milk macronutrient components in prolonged lactation. Nutrients 10, 115.CrossRefGoogle ScholarPubMed
Hoppe, C, Mølgaard, C, Thomsen, BL, et al. (2004) Protein intake at 9 months of age is associated with body size but not with body fat in 10-years-old Danish children. Am J Clin Nutr 79, 494501.CrossRefGoogle Scholar
Desclée de Maredsous, C, Oozeer, R, Barbillon, P, et al. (2016) High-protein exposure during gestation or lactation or after weaning has a period-specific signature on rat pup weight, adiposity, food intake, and glucose homeostasis up to 6 weeks of age. J Nutr 146, 2129.CrossRefGoogle ScholarPubMed
Westerterp-Plantenga, MS, Lemmens, SG & Westerterp, KR (2012) Dietary protein – its role in satiety, energetics, weight loss and health. Br J Nutr 108, Suppl. 2, S105S112.CrossRefGoogle ScholarPubMed
Simonson, M, Boirie, Y & Guillet, C (2020) Protein, amino acids and obesity treatment. Rev Endocr Metab Disord 21, 341353.CrossRefGoogle ScholarPubMed
Paddon-Jones, D, Westman, E, Mattes, RD, et al. (2008) Protein, weight management, and satiety. Am J Clin Nutr 87, 15581561.CrossRefGoogle ScholarPubMed
Cuenca-Sánchez, M, Navas-Carrillo, D & Orenes-Piñero, E (2015) Controversies surrounding high-protein diet intake: satiating effect and kidney and bone health. Adv Nutr 6, 260266.CrossRefGoogle ScholarPubMed
Kratz, M, Baars, T & Guyenet, S (2013) The relationship between high-fat dairy consumption and obesity, cardiovascular, and metabolic disease. Eur J Nutr 52, 124.CrossRefGoogle ScholarPubMed
Rolland-Cachera, MF, Maillot, M, Deheeger, M, et al. (2013) Association of nutrition in early life with body fat and serum leptin at adult age. Int J Obes 37, 11161122.CrossRefGoogle ScholarPubMed
George, AD, Gay, MCL, Murray, K, et al. (2020) Human milk sampling protocols affect estimation of infant lipid intake. J Nutr 150, 29242930.CrossRefGoogle ScholarPubMed
Eckart, EK, Peck, JD, Kharbanda, EO, et al. (2021) Infant sex differences in human milk intake and composition from 1- to 3-month post-delivery in a healthy United States cohort. Ann Hum Biol 48, 455465.CrossRefGoogle Scholar
George, AD, Gay, MCL, Wlodek, ME, et al. (2021) The importance of infants’ lipid intake in human milk research. Nutr Rev 79, 13531361.CrossRefGoogle ScholarPubMed
Scanlon, KS, Alexander, MP, Serdula, MK, et al. (2002) Assessment of infant feeding: the validity of measuring milk intake. Nutr Rev 60, 235251.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Baseline characteristics of the analytic study sample (n 70)

Figure 1

Fig. 1. Correlation between BM intake volume at 4–6 weeks and infant weight gain from 0 to 6 weeks. Two-tailed partial correlation coefficient is presented, adjusted for infant sex and GA. BM, breast milk; GA, gestational age; SDS, standard deviation scores.

Figure 2

Table 2. Associations between BM macronutrient intake at 6 weeks with infant growth and adiposity

Figure 3

Table 3. BM macronutrient concentrations and intakes at 6 weeks

Figure 4

Table 4. Correlations between BM intake volume (measured between 4–6 weeks) and macronutrient concentrations (measured at 6 weeks)

Figure 5

Table 5. Longitudinal associations between BM macronutrient intake and infant growth and adiposity

Figure 6

Fig. 2. Correlation between carbohydrate intake at 6 weeks and infant weight gain. SDS, standard deviation scores.

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