key: cord-1052665-xsjdfayg authors: Rao, Shripada; Esvaran, Meera; Chen, Liwei; Keil, Anthony D.; Gollow, Ian; Simmer, Karen; Wemheuer, Bernd; Conway, Patricia; Patole, Sanjay title: Probiotic supplementation in neonates with congenital gastrointestinal surgical conditions: a pilot randomised controlled trial date: 2022-01-03 journal: Pediatr Res DOI: 10.1038/s41390-021-01884-x sha: 3854cdf78a26536450cc3261979897a656d4d5b1 doc_id: 1052665 cord_uid: xsjdfayg OBJECTIVE: To evaluate whether probiotic supplementation attenuates gut-dysbiosis in neonates with congenital gastrointestinal surgical conditions (CGISC). METHODS: Sixty-one neonates (≥35 weeks gestation) with CGISC were randomised to receive daily supplementation with a triple-strain bifidobacterial probiotic (n = 30) or placebo (n = 31) until discharge. Stool microbiota was analysed using 16S ribosomal RNA gene sequencing on samples collected before (T1), 1 week (T2), and 2 weeks (T3) after supplementation and before discharge (T4). The primary outcome was the sum of the relative abundance of potentially pathogenic families of Clostridiaceae, Enterobacteriaceae, Enterococcaceae, Pseudomonaceae, Staphylococcaeae, Streptococcaceae, and Yersiniaceae at T3. RESULTS: The median gestational age [38 weeks (IQR: 37.1–38.9)] was similar in both groups. The probiotic group had lower rates of caesarean deliveries (40% versus 70%, p = 0.02). The relative abundance of potentially pathogenic families was lower in the probiotic group compared to placebo at T3 [(median: 50.4 (IQR: 26.6–67.6) versus 67.1 (IQR: 50.9–96.2); p = 0.04). Relative abundance of Bifidobacteriaceae was higher in the probiotic group at T3 [(median: 39.8 (IQR: 24.9–52.1) versus 0.03 (IQR 0.02–2.1); p < 0.001). Stratified analysis continued to show a higher abundance of Bifidobacteriaceae in the probiotic group, irrespective of the mode of delivery. CONCLUSIONS: Probiotic supplementation attenuated gut dysbiosis in neonates with CGISC. TRIAL REGISTRATION: http://www.anzctr.org.au (ACTRN12617001401347). IMPACT: Probiotic supplementation attenuates gut dysbiosis and improves stool short-chain fatty acid levels in neonates with congenital gastrointestinal surgical conditions. This is the second pilot RCT of probiotic supplementation in neonates with congenital gastrointestinal conditions. These findings will pave the way for conducting multicentre RCTs in this area. The common morbidities in neonates with congenital gastrointestinal surgical conditions (CGISC) are feed intolerance and healthcareassociated infections (HAI). [1] [2] [3] [4] [5] [6] [7] [8] [9] Recurrent administration of antibiotics, delayed enteral feeds, use of parenteral nutrition (PN), and delayed exposure to the mother's skin and breast milk microbiota can lead to intestinal dysbiosis in these infants. [10] [11] [12] [13] [14] [15] Our previous prospective study found that neonates with CGISC develop gut dysbiosis during their stay in the neonatal intensive care unit. 13 Experimental studies have shown that probiotic supplementation attenuates gut dysbiosis, strengthens the gut barrier, prevents enteropathogenic infections, reduces antimicrobial resistance, enhances immunity, and promotes gut peristalsis. 16 Through these mechanisms, probiotics have the potential to improve the outcomes of neonates with CGISC. 16 Many beneficial biological functions of probiotics are mediated via short-chain fatty acids (SCFAs). 17 The major SCFAs (80-95%) in the gut are acetate, propionate, and butyrate. 18, 19 In infants, SCFAs are produced by the fermentation of milk oligosaccharides by gut bacteria, and the type of milk has a significant effect on the composition of the SCFA. 20 Our previous prospective study also found that neonates with CGISC have lower faecal SCFA levels. 13 Systematic reviews from adult studies have concluded that probiotic/synbiotic supplementation is safe and reduces the risk of postoperative infections. 21 A pilot randomised controlled trial (RCT) (n = 24) in neonates with gastroschisis reported that gut dysbiosis was partially attenuated by the probiotic Bifidobacterium longum subsp. infantis. 22 Our systematic review found limited evidence regarding the role of probiotics in neonates with CGISC and recommended the conduct of RCTs. 23 Hence, we conducted this pilot RCT to evaluate the efficacy and safety of probiotics in attenuating dysbiosis and improving SCFA levels in term and nearterm infants with CGISC. Probiotic supplementation attenuates gut dysbiosis and increases stool SCFA levels in term and near-term neonates with CGISC. Double-blind RCT in the neonatal intensive care unit of Perth Children's Hospital, Western Australia. Approval was obtained from the Institutional Human Research Ethics Committee (HREC Ref Number RGS0000002554). It was registered with the Australia and New Zealand Clinical Trials Registry (ACTRN12617001401347). The protocol is available in Supplement File 3. Infants were recruited between November 2017 and March 2020. Neonates (≥35 weeks' gestation) with intestinal atresia, malrotation, congenital diaphragmatic hernia (CDH), tracheoesophageal fistula (TOF), gastroschisis, exomphalos, Hirschsprung disease, imperforate anus, short bowel syndrome, and other surgical conditions requiring stomas (e.g., severe meconium ileus, microcolon). Preterm infants less than 35 weeks of gestation were excluded to reduce the confounding effect of prematurity on the gut microbiota. A mixture of three strains (Bifidobacterium breve M-16V, Bifidobacterium longum subsp. infantis M-63, and Bifidobacterium longum subsp. longum BB536; 1 × 10 9 colony-forming units (CFU) of each strain per 1 g sachet; Morinaga Milk Industry Co., Ltd., Japan]. Dose was 1 sachet per day, which provided a total of 3 × 10 9 (i.e., 3 billion) CFU per day. Placebo: Maltodextrin. The trial supplements were stored in a refrigerator at 2-8°C. Group assignments were allocated using a computer-generated sequence in randomly ordered block sizes of 2 and 4. These sequences were generated by our institutional trial pharmacist, without the involvement of the research team. Allocation concealment was optimised through pharmacy-controlled allocation; the clinical trial pharmacist generated random numbers and used them to prepare sequentially numbered individual boxes, each containing 30 sachets of trial supplements. The sachets containing probiotics or placebo were of identical design, weight, and volume; the boxes containing the sachets were also of similar design. The contents of the sachets (probiotic or placebo) were similar in texture, smell, and taste. All these steps were undertaken to ensure adequate blinding of healthcare providers and parents. Once parental consent was obtained, the chief investigator or his delegate allocated the next box of study supplement to the infant without knowledge of the contents of the box (probiotic or placebo). In the postoperative period, once baseline stool samples were collected, infants were given trial supplements once daily until discharge. Trial supplements were dissolved in 1.5 mL of expressed breast milk (EBM) or sterile water (if EBM was not available) and administered via the feeding tube or mouth. Supplementation was continued even when the infants did not receive enteral feeds. If an infant was having continuous or intermittent gastric suctioning, once the trial supplements were given, suctioning was stopped for 3-4 h prior to recommencing. The standard policy of our unit is to commence PN within 48-72 h of admission for surgical infants who are unable to tolerate enteral feeds. Enteral feeding with expressed breast milk were commenced as soon as possible in the postoperative period (usually on postoperative day 2 and advanced as tolerated), depending on the underlying surgical condition and consensus opinion of neonatologists and surgeons. Infant formulae or hydrolysed formulae are rarely used in our unit for surgical infants. None of our study infants received donor breast milk because it was reserved for preterm infants less than 32 weeks of gestation in our unit. Stool samples were collected at four time points: (a) as soon as possible after admission, but before commencing trial supplements (T1); (b) 1 week (T2), and (c) 2 weeks after commencing supplements (T3); and (d) prior to discharge (T4). The samples were collected from the nappies into sterile microvials and stored in the NICU at −20°C for 3-4 days and subsequently at −80°C. At the completion of full recruitment, samples were shipped on dry ice to the University of New South Wales (Sydney, Australia), where microbial analysis was undertaken. Acidified samples were frozen at −20°C and shipped to the School of Chemical and Biomedical Engineering, Nanyang Technological University, Singapore, where SCFA analysis was performed. The stool microbiota was assessed using the 16S ribosomal RNA gene sequencing method (Supplementary File 1). Stool short-chain fatty acid assay was performed according to our previously described method 13 with slight modifications (Supplementary File 1). The scientists who conducted microbial and SCFA assays and their respective statistical analyses were blinded to the randomisation groups. They conducted statistical analyses of data from stool samples as group 1 versus group 2. The trial pharmacist disclosed the groupings only after receiving all the results through e-mail. This ensured adequate blinding of clinicians, research teams, lab scientists, and statisticians throughout all stages of the trial. The primary outcome was the sum of the relative abundance of potentially pathogenic families of Clostridiaceae, Enterobacteriaceae, Enterococcaceae, Pseudomonaceae, Staphylococcaeae, Streptococcaceae, and Yersiniaceae at T3 using 16S ribosomal RNA gene sequencing methods. T3 was chosen as the main time point of interest because 2 weeks is a reasonable duration of supplementation to enable colonisation by the probiotic strains, and many study infants will still be in the hospital. (1) Stool microbiota at T1, T2, and T4 time points; (2) SCFA levels at all time points: (3) short-term clinical outcomes during initial stay in the NICU, such as incidence of mortality, HAI, duration of antibiotics, PN, hospital stay, time to reach full feeds after surgery, and physical growth. The z-scores for weight, length, and head circumference at birth were calculated using the Fenton growth charts 24 and at discharge using the WHO charts 25 through the publicly accessible PediTools website of clinical calculators. 26 Sample size estimation. In a recent RCT, the sum of the relative abundance of potentially pathogenic families such as Enterobacteriaceae, Staphylococcaeae, Enterococcaceae, Clostridiaceae, and Streptococcaceae was approximately 76% in the stools of infants with gastroschisis who received placebo. 22 Hence, we calculated that a total sample size of 60 infants (probiotic: 30, placebo: 30) would be required to demonstrate a 50% reduction of potentially pathogenic bacterial families from 76 to 38% after 2 weeks of supplementation with probiotics with an alpha error of 0.05, and a power of 80%. Statistical analysis of clinical data. Continuous data with normal distribution were summarised using mean and standard deviations (SD) and compared using the two-sample t-test. Median, interquartile range (IQR), and range were used to summarise data with skewed distribution and compared using the Wilcoxon rank-sum test. Binary outcomes were compared using the Fisher's exact test. To compare the z-scores of physical growth parameters at discharge versus birth, the matched pairs t-test was used. For all analyses, a p value less than 0.05 was considered significant. Statistical analysis for microbiological data. Analyses were conducted with R version 3.6.0. For microbial richness, linear mixed model effects (LME) test (MASS, lme4, and lmerTest packages) was used to identify if there were significant differences between the groups over time. In our LME model, Subject ID was a random factor, while time and treatment were used as fixed factors. Post hoc pairwise comparisons were performed using Tukey's HSD method to adjust for multiple comparisons. Wilcoxon rank-sum test with Benjamini-Hochberg correction to adjust for multiple testing was used to identify differences between the groups at the various time points. For beta diversity, PERMANOVA was used to check if community structures differed between the groups at the various time points followed by pairwise.adonis test (https://github.com/bwemheu/pairwise. adonis) for pairwise comparisons between the groups. P values were adjusted for multiple testing using the Benjamini-Hochberg correction. Taxa significantly different between the groups were identified at the phylum, class family, and genus levels using analysis of the analysis of the composition of the microbiome (ANCOM; v2.0). 27 ANCOM compares the logratio abundance of each taxon among multiple groups to all the remaining taxa. It uses the Kruskal-Wallis test to assess significant differences, with multiple testing corrected by the Benjamini-Hochberg (BH) false discovery rate. For this study, we accepted the W-statistic cutoff of 0.7 from the ANCOM output to define taxa as significantly different. Pairwise comparisons in the groups over time was then determined using our LME model. For pairwise comparison of the taxa at T3, Wilcoxon rank-sum test with BH correction was used. For all microbiota and SCFA analysis an adjusted p value of <0.05 was considered significant. Statistical analysis of SCFA data. Wilcoxon's rank analysis with BH correction was performed to compare SCFA concentrations between the two groups (probiotics and placebo) at the different time points. An independent data safety and monitoring committee (DSMC) reviewed the data at 50% of recruitments and advised to continue the study. The safety issues that arose during the early stages of the trial are described in Supplementary File 1. The CONSORT checklist (Supplementary File 2) was used to report the results of this RCT. 28 The study recruitment was completed in March 2020 after achieving full sample size. A total of 61 infants were randomised to receive either probiotics (n = 30) or placebo (n = 31). All infants received the trial supplements as per original randomisation without any crossovers. All infants were analysed as per the original assigned groups. Figure 1 shows a CONSORT flow diagram. Table 1 presents the clinical details of the study infants. The median gestational age, birth weight, Apgar scores, cord pH, and lactate levels were similar between the two groups. The incidence of maternal pregnancy- induced hypertension (PIH), chorioamnionitis, and peripartum antibiotics was similar between the groups. The incidence of antepartum haemorrhage (APH) was higher, and caesarean delivery rates were lower in the probiotic group. The probiotic group had more infants with congenital diaphragmatic hernia than the placebo group. The median age at surgery was 2 days in both the groups. The median age at commencement of supplementation was approximately 7 days in both groups, and the duration of supplementation was 16-18 days. Of the 61 recruited infants, stool samples were available for 61, 58, 39, and 29 infants at time points T1, T2, T3, and T4, respectively. The attrition in sample size was because 22 infants were discharged home before completing 2 weeks of supplementation (i.e., before reaching T3). We could not extend the trial beyond March 2020 to recruit additional infants because of severe restrictions that were implemented due to the COVID-19 pandemic during that period. Alpha diversity (i.e., Richness and Shannon diversity index) was comparable between the two groups at all time points (all p > 0.05; Fig. 2a ). Similar results were obtained on Chao1 and ACE estimations (data not shown). Observed OTUs increased in both groups over time and the probiotic group displayed significantly increased bacterial richness at T4 compared to T1 (p = 0.015) and T2 (p < 0.01; Fig. 2a ). Beta diversity analysis revealed that both groups had similar community structures at T1 (p = 0.807; Fig. 2b ). However, at T2, T3, and T4, the community structures of the probiotic group were significantly different from those of the placebo group (all p < 0.05; Fig. 2b ). Comparisons at the bacterial phylum level. Actinobacteria, Bacteroidetes, Cyanobacteria, Firmicutes, and Proteobacteria were the most common phyla in the stool samples (e- Fig.1A in Supplementary File 1). The median relative abundance of Actinobacteria was significantly higher in the probiotic group than in the placebo group at T3 (40.1% versus 0.1%; p < 0.0001) and at T2 and T4 (both p < 0.01; e- Stool SCFAs: The total SCFA levels were higher in the probiotic group than in the placebo group at T3 (p = 0.008; Fig. 4 ). Acetate levels were higher in the probiotic group (e- Fig. 5 in Supplementary File 1). The butyrate levels were similar between the groups at all time points except T2, when they were lower in the probiotic group (e- Fig. 6 in Supplementary File 1). The propionate levels were similar between the two groups at all time points (e- Fig. 7 in Supplementary File 1). Post hoc subgroup analysis based on the mode of delivery Since the probiotic group had significantly lower rates of caesarean section, we conducted a post hoc analysis separately for infants born via caesarean section and through the vaginal route. The results showed a significantly higher abundance of Bifidobacteriaceae in the Fig. 2 Alpha and Beta diversity at various time points in the stool samples of study infants. a Alpha diversity. Richness and the Shannon diversity index were similar between the probiotic and placebo groups at all time points (all p > 0.05). b Beta diversity as measured by weighted unifrac by time point. At baseline, infants in the probiotic group had similar community structures to the placebo group (p = 0.807). However, at subsequent time points T2, T3, and T4, the community structures of the probiotic group were significantly different from the placebo group (all p < 0.05). probiotic group, irrespective of the mode of delivery. However, the beneficial effects of supplementation on SCFA levels were significant only in infants born by caesarean section. The relative abundance of pathogenic families was not statistically significant in either mode of delivery, even though the trend was in favour of probiotics (Table 2) . All participating infants survived. There were no significant differences between the groups in the incidence of HAI, duration of antibiotics, PN, hospital stay, and time to reach full feeds after surgery (Table 3 ). All routine clinical specimens (blood, urine, CSF, endotracheal secretions, wound swabs) from study infants were analysed using aerobic and anaerobic culture methods. There were no cases of infections due to the administered probiotics. The z-scores for weight were significantly lower at discharge than at birth in the probiotic and placebo groups (both p < 0.0001; e- Fig. 8 in Supplementary File 1) . The degree of postnatal growth restriction for weight was similar between the two groups (−0.93 in the probiotic and −0.79 in the placebo; p = 0.486; Table 1 , e- Fig. 9 in Supplementary File 1) . The z-scores for head circumference were lower at discharge than at birth in both the probiotic and placebo groups (both p < 0.0001; e- Fig. 10 in Supplementary File 1) . However, postnatal growth restriction for head circumference was less severe in the probiotic group (p = 0.013; Table 1 and Fig. 5 ). The z-scores for length at discharge were similar to those at birth in both the probiotic and placebo groups (e- Fig. 11 ). The degree of postnatal growth restriction for length was similar between the two groups (e- Fig. 12 ). This pilot RCT found that after 2 weeks of supplementation with the three-strain bifidobacterial probiotic, neonates with CGISC had a lower relative abundance of potentially pathogenic bacterial families, higher abundance of bifidobacteria, and higher SCFA levels in their stools compared to placebo. Postnatal growth restriction for head circumference was less severe in the probiotic group than in the placebo group. Other clinical outcomes were similar between the two groups. No infections related to the administered probiotic organisms were observed. These results provide reassurance regarding the use of this probiotic in neonates with CGISC. The only other RCT in neonates with surgical conditions was by Powell et al., 22 in which 24 infants with gastroschisis were supplemented with Bifidobacterium longum subsp. infantis ATCC 15697 or placebo. In their study, the daily dose was 2 × 10 9 CFU compared with 3 × 10 9 CFU in our study. Similar to their study, the majority of our infants received breast milk as the sole source of diet, trial supplements were commenced in the postoperative period, and given for a median duration of 3 weeks. Similar to their study, the relative abundance of Bifidobacteriaceae increased to 40% after commencing supplements in the probiotic group and remained at 3% in the placebo group. In line with the recent literature, our study found that neonates with CGISC develop postnatal growth restriction for weight and head circumference. 29, 30 Studies in preterm infants have reported an association between postnatal growth restriction of the head circumference and adverse developmental outcomes. [31] [32] [33] Hence, it was reassuring that postnatal growth restriction for head circumference was less severe in the probiotic group in our RCT. Similar beneficial effects of probiotics on head circumference were observed in extremely low birth weight infants in recent RCTs. 34, 35 In our current RCT, SCFA levels were significantly higher in the probiotic group at T3 than in the placebo group, mainly due to elevated acetates. Even though the levels were also higher at T2 and T4, they were not statistically significant, probably because infants would have received only 1 week of supplementation by T2, whereas by T4, the sample size was very small. Bifidobacteria are known to ferment HMOs and produce acetate as a byproduct. 36 Bifidobacteria are not butyrogenic, and hence butyrate levels were not elevated in the probiotic group in our study. While it has been suggested that acetate and lactate produced by bifidobacteria can be used as a substrate by other commensal bacteria (cross-feeding) 37 to produce butyrate, thereby increasing its levels, this was not observed in our study. The relative abundance of Proteobacteria, considered to be the microbial signature of gut dysbiosis, 38 was lower in the probiotic Table 2 . Effect of probiotics supplementation at T3, based on route of delivery. Bold values indicate statistical significance p < 0.05. interquartile range, SCFA short-chain fatty acid, T3 two weeks after commencing supplementation. S. Rao et al. group than in the placebo group (22.7% versus 50.3%), but the differences were not statistically significant. Studies with larger sample sizes are needed to determine if this difference is real. Although not statistically significant, hospital stay was longer in the probiotic group (27 versus 20 days, p = 0.095). We speculate that this was because the probiotic group had more infants with complex conditions such as CDH and gastroschisis, and fewer infants with imperforate anus. It was reassuring that none of the infants developed infection due to the administered bifidobacterial strains. There are case reports of bifidobacterial sepsis in surgical infants and preterm infants without surgical conditions. 39, 40 Hence, ongoing microbiological surveillance is important when conducting probiotic RCTs. In our study infants, the use of exclusive breast milk dropped to 70-80% by discharge compared to 93-100% at birth. However, the use of formula milk was similar between the two groups (20% in the probiotic group versus 29% in the placebo group; p = 0.554). The common reasons for the use of formula milk were inadequate production of breast milk and mother's choice. Some studies have suggested that probiotics are more effective in infants who are breastfed rather than formula. [41] [42] [43] Given such findings and overall benefits of breast milk, every effort should be made to encourage breastfeeding and to express breast milk during hospital stay and after discharge in these infants. While our study did not specifically address the issue of crosscontamination (aka cross-colonisation), 44 the relative abundance of the genus Bifidobacterium in the placebo group was only 5% at all time points T2-T4, versus 35-45% in the probiotic group. Hence, even if there was cross-contamination, the load was not Fig. 5 Comparison of the degree of postnatal growth restriction for head circumference in study infants. The degree of postnatal growth restriction for head circumference was less severe in the probiotic group than in the placebo group. enough to allow them to colonise adequately in the placebo group and, hence, unlikely to be clinically significant. An important limitation of our study was the higher rates of caesarean delivery in the placebo group. Infants born by caesarean delivery are known to have a lower abundance of bifidobacteria in the first few months of life. 45 In this context, it was reassuring to know that even in subgroup analysis, the probiotic supplemented group had higher bifidobacterial counts. Our findings are similar to Frese et al. 46 who reported that supplementation resulted in higher colonisation with bifidobacteria, which persisted even after supplementation was ceased, whether the infants were born vaginally or by caesarean section. Since many factors such as gestational diabetes, 47 mode of delivery, 45 intrapartum antibiotics [48] [49] [50] and maternal probiotics [51] [52] [53] can affect neonatal gut microbiota, it is difficult to achieve a balance between the two groups for all such variables in small RCTs. Future studies should consider using the technique of "allocation by minimisation" 54 to ensure adequate balance. In addition to maternal factors, important neonatal variables to be balanced include gestational age 55 and underlying surgical conditions. Since the type of milk used (breast milk versus cow's milk based versus hydrolysed formula) can influence gut microbiota, 56 standardising their feeding regimen is desirable, but may not be feasible, given that multiple factors can influence milk production and its content. One option is to use pasteurised human donor milk, but the quantity required will be enormous because majority of these infants are born at term or near term, rather than at an extremely preterm gestation, in whom the quantity required is small. RCTs with large sample size have the potential to minimise the risk of imbalance in two groups regarding the type of milk used and other variables. Another limitation of our study was that 16S rRNA gene sequencing allowed the allocation of reads only up to the genus level. Hence, it was not possible to confirm whether the increase in the relative abundance of Bifidobacterium in the probiotic group was due to the administered strains. A whole-metagenome approach that provides species-and strain-level information needs to be incorporated in future studies. Another limitation of the study was that stool samples from only 39 of the 61 study infants were available for analysis at T3, because others were discharged home by then. While surgical conditions included in our RCT were heterogeneous, all of them had common issues such as feed intolerance, need for PN, and risk of infections. Hence, we decided to include all types of gastrointestinal surgical conditions in this pilot RCT. Another reason was because it would have taken at least 7-9 years to achieve the sample size of 60 if we had conducted it in a single surgical condition (for example, our unit admits only 10 cases of gastroschisis per year). There is some observational evidence from adult literature that maltodextrin may lead to adverse health outcomes secondary to alterations in gut microbiota. 57 In our RCT, the probiotic supplement contained probiotic organisms and maltodextrin, whereas placebo was only maltodextrin. Hence, any effect of maltodextrin on gut microbiota would have occurred in both placebo and probiotic groups. To evaluate the effects of maltodextrin (at the small dose of 1 gram per day as used in our trial) on gut microbiota, prospective cohort studies comparing gut microbiota in healthy breastfed infants receiving maltodextrin versus healthy breastfed infants are needed. The important strengths of our study are as follows: (a) It is the first RCT to evaluate the efficacy and safety of the three-strain bifidobacterial supplementation in CGISC in neonates and (b) all study infants had baseline stool samples prior to commencing supplements. The current pilot RCT found that the degree of postnatal growth restriction of head circumference was less severe in the probiotic supplemented group than placebo. Hence, one could hypothesise that probiotic supplemented group will have better neurodevelopmental outcomes. Our recent retrospective study 30 with a sample size of 400 found the incidence of suboptimal neurodevelopmental outcomes (SNDO) to be 16% in term and nearterm neonates with CGISC. A sample size of 516 infants (258 in each arm) will be required to have 80% power at the two-sided 5% significance level to detect a 50% difference in the primary outcome (16% in controls and 8% in the probiotic group). Since nearly 30% of them are expected to be discharged home even before completing 2 weeks of supplementation, the sample size should be increased by another 154, and hence the final sample size will be around 670 infants. With such a large sample size, baseline frequencies of potential confounders such as gestational age, maternal antibiotics, maternal probiotic usage, mode of delivery, severity of illness and type of milk feeds are expected to be balanced between the two groups. Involvement of multiple centres will be crucial to achieve this sample size within a reasonable time period of 24-36 months. In summary, this pilot RCT found that after 2 weeks of supplementation with the three-strain Bifidobacterium, neonates with CGISC had a lower relative abundance of potentially pathogenic bacterial families, higher abundance of Bifidobacterium, and higher SCFA levels in their stools. Larger studies with clinical endpoints and long-term follow-ups are necessary. 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Ms. Margaret Shave and Ms. Thanh Tan for help with receiving the trial supplements, generating random sequence numbers, providing trial supplements for administration to study infants, and for maintaining audits. Members of the Data Safety and Monitoring Committee: Prof. Tobias Strunk (neonatologist) and Mr. Naeem Samnakay (paediatric surgeon). Medical scientific staff at PathWest Laboratory Medicine WA for performing microbial analysis of sachets. The nursing staff at Perth Children's Hospital for collecting stool samples and administering trial supplements to study infants. Mr. Damber Shrestha for providing data from the neonatal database. Ms. Emma Anderton, Ms. Julie Hibbert, and Ms. Jamee Murdoch for processing the stool samples and storing them in a deep freezer at −80°C. Ms. Yen Kok for helping with organising the shipment of stool samples to the lab at the University of New South Wales. Centre for Neonatal Research and Education, Neonatal Directorate, King Edward Memorial Hospital for Women, Western Australia for providing funds. Parents of study infants for providing informed consent for participation in the RCT. Study infants for participating in the RCT. Centre for Neonatal Research and Education, Neonatal Directorate, Child and Adolescent Health Service, Western Australia. The authors declare no competing interests. Supplementary information The online version contains supplementary material available at https://doi.org/10.1038/s41390-021-01884-x.Correspondence and requests for materials should be addressed to Shripada Rao.Reprints and permission information is available at http://www.nature.com/ reprintsPublisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.