Effect of a reduced fat and sugar maternal dietary intervention during lactation on the infant gut microbiome

PUBLISHED 17 August 2022Objective: A growing body of literature has shown that maternal diet during pregnancy is associated with infant gut bacterial composition. However, whether maternal diet during lactation affects the exclusively breastfed infant gut microbiome remains understudied. This study sets out to determine whether a two-week of a reduced fat and sugar maternal dietary intervention during lactation is associated with changes in the infant gut microbiome composition and function. Design: Stool samples were collected from four female and six male (n = 10) infants immediately before and after the intervention. Maternal baseline diet from healthy mothers aged 22–37 was assessed using 24-h dietary recall. During the 2-week dietary intervention, mothers were provided with meals and their dietary intake was calculated using FoodWorks 10 Software. Shotgun metagenomic sequencing was used to characterize the infant gut microbiome composition and function. Results: In all but one participant, maternal fat and sugar intake during the intervention were significantly lower than at baseline. The functional capacity of the infant gut microbiome was significantly altered by the intervention, with increased levels of genes associated with 28 bacterial metabolic pathways involved in biosynthesis of vitamins (p = 0.003), amino acids (p = 0.005), carbohydrates (p = 0.01), and fatty acids and lipids (p = 0.01). Although the dietary intervention did not affect the bacterial composition of the infant gut microbiome, relative difference in maternal fiber intake was positively associated with increased abundance of genes involved in biosynthesis of storage compounds (p = 0.016), such as cyanophycin. Relative difference in maternal protein intake was negatively associated with Veillonella parvula (p = 0.006), while positively associated with Klebsiella michiganensis (p = 0.047). Relative difference in maternal sugar intake was positively associated with Lactobacillus paracasei (p = 0.022). Relative difference in maternal fat intake was positively associated with genes involved in the biosynthesis of storage compounds (p = 0.015), fatty acid and lipid (p = 0.039), and metabolic regulator (p = 0.038) metabolic pathways. Conclusion: This pilot study demonstrates that a short-term maternal dietary intervention during lactation can significantly alter the functional potential, but not bacterial taxonomy, of the breastfed infant gut microbiome. While the overall diet itself was not able to change the composition of the infant gut microbiome, changes in intakes of maternal protein and sugar during lactation were correlated with changes in the relative abundances of certain bacterial species. Clinical trial registration: Australian New Zealand Clinical Trials Registry (ACTRN12619000606189).Azhar S. Sindi, Lisa F. Stinson, Soo Sum Lean, Yit-Heng Chooi, Gabriela E. Leghi, Merryn J. Netting, Mary E. Wlodek, Beverly S. Muhlhausler, Donna T. Geddes and Matthew S. Payn

Human milk lactose, insulin, and glucose relative to infant body composition during exclusive breastfeeding

Human milk (HM) components may influence infant growth and development. This study aimed to investigate relationships between infant body composition (BC) and HM lactose, insulin, and glucose (concentrations and calculated daily intakes (CDI)) as well as 24-h milk intake and maternal BC at 3 months postpartum. HM samples were collected at 2 months postpartum. Infant and maternal BC was assessed with bioimpedance spectroscopy. Statistical analysis used linear regression accounting for infant birth weight. 24-h milk intake and CDI of lactose were positively associated with infant anthropometry, lean body mass and adiposity. Higher maternal BC measures were associated with lower infant anthropometry, z-scores, lean body mass, and adiposity. Maternal characteristics including BC and age were associated with concentrations and CDI of HM components, and 24-h milk intake. In conclusion, 24-h intake of HM and lactose as well as maternal adiposity are related to development of infant BC

Can we modulate the breastfed infant gut microbiota through maternal diet?

Initial colonisation of the infant gut is robustly influenced by regular ingestion of human milk, a substance that contains microbes, microbial metabolites, immune proteins and oligosaccharides. Numerous factors have been identified as potential determinants of the human milk and infant gut microbiota, including maternal diet; however, there is limited data on the influence of maternal diet during lactation on either of these. Here, we review the processes thought to contribute to human milk and infant gut bacterial colonisation and provide a basis for considering the role of maternal dietary patterns during lactation in shaping infant gut microbial composition and function. Although only one observational study has directly investigated the influence of maternal diet during lactation on the infant gut microbiome, data from animal studies suggests that modulation of the maternal gut microbiota, via diet or probiotics, may influence the mammary or milk microbiota. Additionally, evidence from human studies suggests that the maternal diet during pregnancy may affect the gut microbiota of the breastfed infant. Together, there is a plausible hypothesis that maternal diet during lactation may influence the infant gut microbiota. If substantiated in further studies, this may present a potential window of opportunity for modulating the infant gut microbiome in early life.Azhar S Sindi, Donna T Geddes, Mary E Wlodek, Beverly S Muhlhausler, Matthew S Payne, Lisa F Stinso

Impact of expression mode and timing of sample collection, relative to milk ejection, on human milk bacterial DNA profiles

Aim To investigate the impact of expression mode: electric breast pump or hand expression, and timing of sample collection: pre‐ and post‐milk ejection on human milk (HM) bacterial DNA profiles. Methods and results Three HM samples from the same breast were collected from 30 breastfeeding mothers: a pre‐milk ejection pump‐expressed sample (pre‐pump), a post‐milk ejection pump‐expressed sample (post‐pump) and a post‐milk ejection hand‐expressed sample (post‐hand). Full‐length 16S rRNA gene sequencing was used to assess milk bacterial DNA profiles. Bacterial profiles did not differ significantly based on mode of expression nor timing of sample collection. No significant differences were detected in the relative abundance of any OTUs based on expression condition (pre‐pump/ post‐pump and post‐pump/post‐hand) with univariate linear mixed‐effects regression analyses (all P‐values > 0·01; α = 0·01). Similarly, no difference in richness was observed between sample types (number of observed OTUs: post‐pump/post‐hand P = 0·13; pre‐pump/post‐pump P = 0. 45). Conclusion Bacterial DNA profiles of HM did not differ according to either expression method or timing of sample collection. Significance and Impact of the Study Hand or pump expression can be utilized to collect samples for microbiome studies. This has implications for the design of future HM microbiome studies

The duration of fetal antenatal steroid exposure determines the durability of preterm ovine lung maturation

Objective Antenatal corticosteroids (ACS) are the standard of care for maturing the fetal lung and improving outcomes for preterm infants. ACS dosing remains un-optimized, and there is little understanding of how different treatment to delivery intervals may affect treatment efficacy. The durability of a lung maturational response is important because the majority of women treated with ACS do not deliver within the widely accepted 1-7 day window of treatment efficacy. We used a sheep model to test duration of fetal exposures for efficacy at delivery intervals from 1 to 10 days. Methods For infusion studies, ewes with single fetuses were randomised to receive an intravenous bolus and maintenance infusion of betamethasone phosphate to target 1-4ng/mL fetal plasma betamethasone for 36 hours, with delivery at either 2, 4 or 7 days-post treatment or sterile saline as control. Animals receiving the clinical treatment were randomised to receive either:i) a single injection of 0.25mg/kg with a 1:1 mixture of betamethasone phosphate + betamethasone acetate with delivery at either 1 or 7 days post treatment; or ii) two treatments of 0.25 mg/kg betamethasone phosphate + betamethasone acetate spaced at 24 hours (giving approximately 48 hours of fetal steroid exposure) with delivery at 2, 5, 7 or 10 days post-treatment. Negative control animals were treated with saline. All lambs were delivered at 121±3 days gestational age and ventilated for 30 minutes to assess lung function. Results Preterm lambs delivered at 1 or 2 days post-ACS treatment had significant improvements in lung maturation for both intravenous and single dose intramuscular treatments. After 2 days the efficacy of 36 hour betamethasone phosphate infusions was lost. The single dose of 1:1 betamethasone phosphate + betamethasone acetate also was ineffective at 7 days. In contrast, animals treated with two doses had significant improvements in lung maturation at 2, 5 and 7 days, with treatment efficacy reduced by 10 days. Conclusion In preterm lambs, the durability of ACS treatment depends on the duration of fetal exposure and is independent of the IV or IM maternal route of administration. For acute 24-48 hour post-treatment deliveries, a 24 hour fetal ACS exposure was sufficient for lung maturation. A fetal exposure duration of at least 48 hours was necessary to maintain long-term treatment durability. A single dose ACS treatment should be sufficient for women delivering within <48 hours of ACS treatment