Pingping Jiang scite author profile

Our results indicate that it is feasible to use BC as a supplement to MM during the first weeks of life to increase enteral protein intake in preterm infants. Plasma tyrosine levels may be a good marker for excessive protein intake. A larger randomized trial is required to test the safety and possible short- and long-term clinical benefits of BC supplementation during the first weeks of life for preterm infants.

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Delayed development of systemic immunity in preterm pigs as a model for preterm infants

Nguyen

Jiang

Frøkiær

et al. 2016

Sci Rep

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Preterm neonates are highly sensitive to systemic infections in early life but little is known about systemic immune development following preterm birth. We hypothesized that preterm neonates have immature systemic immunity with distinct developmental trajectory for the first several weeks of life, relative to those born at near-term or term. Using pigs as a model, we characterized blood leukocyte subsets, antimicrobial activities and TLR-mediated cytokine production during the first weeks after preterm birth. Relative to near-term and term pigs, newborn preterm pigs had low blood leukocyte counts, poor neutrophil phagocytic rate, and limited cytokine responses to TLR1/2/5/7/9 and NOD1/2 agonists. The preterm systemic responses remained immature during the first postnatal week, but thereafter showed increased blood leukocyte numbers, NK cell proportion, neutrophil phagocytic rate and TLR2-mediated IL-6 and TNF-α production. These immune parameters remained different between preterm and near-term pigs at 2–3 weeks, even when adjusted for post-conceptional age. Our data suggest that systemic immunity follows a distinct developmental trajectory following preterm birth that may be influenced by postnatal age, complications of prematurity and environmental factors. Consequently, the immediate postnatal period may represent a window of opportunity to improve innate immunity in preterm neonates by medical, antimicrobial or dietary interventions.

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Marked methylation changes in intestinal genes during the perinatal period of preterm neonates

et al. 2014

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BackgroundThe serious feeding- and microbiota-associated intestinal disease, necrotizing enterocolitis (NEC), occurs mainly in infants born prematurely (5-10% of all newborns) and most frequently after formula-feeding. We hypothesized that changes in gene methylation is involved in the prenatal maturation of the intestine and its response to the first days of formula feeding, potentially leading to NEC in preterm pigs used as models for preterm infants.ResultsReduced Representation Bisulfite Sequencing (RRBS) was used to assess if changes in intestinal DNA methylation are associated with formula-induced NEC outbreak and advancing age from 10 days before birth to 4 days after birth. Selected key genes with differentially methylated gene regions (DMRs) between groups were further validated by HiSeq-based bisulfite sequencing PCR and RT-qPCR to assess methylation and expression levels. Consistent with the maturation of many intestinal functions in the perinatal period, methylation level of most genes decreased with advancing pre- and postnatal age. The highest number of DMRs was identified between the newborn and 4 d-old preterm pigs. There were few intestinal DMR differences between unaffected pigs and pigs with initial evidence of NEC. In the 4 d-old formula-fed preterm pigs, four genes associated with intestinal metabolism (CYP2W1, GPR146, TOP1MT, CEND1) showed significant hyper-methylation in their promoter CGIs, and thus, down-regulated transcription. Methylation-driven down-regulation of such genes may predispose the immature intestine to later metabolic dysfunctions and severe NEC lesions.ConclusionsPre- and postnatal changes in intestinal DNA methylation may contribute to high NEC sensitivity in preterm neonates. Optimizing gene methylation changes via environmental stimuli (e.g. diet, nutrition, gut microbiota), may help to make immature newborn infants more resistant to gut dysfunctions, both short and long term.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-716) contains supplementary material, which is available to authorized users.

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Pasteurization Procedures for Donor Human Milk Affect Body Growth, Intestinal Structure, and Resistance against Bacterial Infections in Preterm Pigs

Nguyen

Waard³

et al. 2017

The Journal of Nutrition

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Holder pasteurization (HP) destroys multiple bioactive factors in donor human milk (DM), and UV-C irradiation (UVC) is potentially a gentler method for pasteurizing DM for preterm infants. We investigated whether UVC-treated DM improves gut maturation and resistance toward bacterial infections relative to HP-treated DM. Bacteria, selected bioactive components, and markers of antioxidant capacity were measured in unpasteurized donor milk (UP), HP-treated milk, and UVC-treated milk (all from the same DM pool). Fifty-seven cesarean-delivered preterm pigs (91% gestation; ratio of males to females, 30:27) received decreasing volumes of parental nutrition (average 69 mL · kg · d) and increasing volumes of the 3 DM diets ( = 19 each, average 89 mL · kg · d) for 8-9 d. Body growth, gut structure and function, and systemic bacterial infection were evaluated. A high bacterial load in the UP (6×10 colony forming units/mL) was eliminated similarly by HP and UVC treatments. Relative to HP-treated milk, both UVC-treated milk and UP showed greater activities of lipase and alkaline phosphatase and concentrations of lactoferrin, secretory immunoglobulin A, xanthine dehydrogenase, and some antioxidant markers (all < 0.05). The pigs fed UVC-treated milk and pigs fed UP showed higher relative weight gain than pigs fed HP-treated milk (5.4% and 3.5%), and fewer pigs fed UVC-treated milk had positive bacterial cultures in the bone marrow (28%) than pigs fed HP-treated milk (68%) ( < 0.05). Intestinal health was also improved in pigs fed UVC-treated milk compared with those fed HP-treated milk as indicated by a higher plasma citrulline concentration (36%) and villus height (38%) ( < 0.05) and a tendency for higher aminopeptidase N (48%) and claudin-4 (26%) concentrations in the distal intestine ( < 0.08). The gut microbiota composition was similar among groups except for greater proportions of in pigs fed UVC-treated milk than in pigs fed UP and those fed HP-treated milk in both cecum contents (20% and 10%) and distal intestinal mucosa (24% and 20%) (all < 0.05). UVC is better than HP treatment in preserving bioactive factors in DM. UVC-treated milk may induce better weight gain, intestinal health, and resistance against bacterial infections as shown in preterm pigs as a model for DM-fed preterm infants.

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Bacterial Colonization Affects the Intestinal Proteome of Preterm Pigs Susceptible to Necrotizing Enterocolitis

Jiang¹,

Sangild²,

Sit³

et al. 2010

Neonatology

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Background: In newborns, colonizing bacteria and enteral nutrition are important for early gut development and immunity. However, in preterm newborns, bacterial colonization, coupled with enteral feeding, can lead to marked intestinal inflammation and disease such as necrotizing enterocolitis (NEC). We hypothesized that the initial bacterial colonization of the gut affects the intestinal proteome independently of enteral feeding. Objective: To identify the intestinal proteins affected by the first colonizing bacteria by comparing the intestinal proteome in formula-fed preterm pigs reared under germ free (GF) or conventional conditions. Methods: Gel-based proteomics of the small intestine to detect proteins that may play a part in the response of the immature intestine to bacterial colonization after birth. Results: Fourteen proteins involved in stress response and detoxification (e.g. heat-shock proteins, peroxiredoxin 1), tissue metabolism and apoptosis (e.g. annexin 2), and some signal transduction pathways were differentially expressed between GF and conventionally reared pigs. Conclusion: The premature intestine is highly responsive to initial bacterial colonization and the specific bacteria-related proteome changes may contribute to the stress response that makes the immature intestine sensitive to the pro-inflammatory effects of enteral feeding.

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Pingping Jiang

Bovine Colostrum for Preterm Infants in the First Days of Life

Delayed development of systemic immunity in preterm pigs as a model for preterm infants

Marked methylation changes in intestinal genes during the perinatal period of preterm neonates

Pasteurization Procedures for Donor Human Milk Affect Body Growth, Intestinal Structure, and Resistance against Bacterial Infections in Preterm Pigs

Bacterial Colonization Affects the Intestinal Proteome of Preterm Pigs Susceptible to Necrotizing Enterocolitis

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