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Synbiotic (L. plantarum Dad-13 and Fructo-oligosaccharide) Powder on Gut Microbiota (L. plantarum, Bifidobacterium and Enterobacteriaceae) on Stunting Children in Yogyakarta, Indonesia

Delima Citra Dewi Gunawan1 , Mohammad Juffrie2, Siti Helmyati3 , Endang Sutriswati Rahayu4,5,6*

1Doctoral program in Medicine, Faculty of Medicine, Public Health and Nursing, Universitas Gadjah Mada, Jl. Farmako, Senolowo, Sekip Utara, Yogyakarta, Indonesia.

2Departement of Pediatric, Faculty of Medicine, Public Health and Nursing, Universitas Gadjah Mada, Jl. Farmako, Senolowo, Sekip Utara, Yogyakarta, 55281, Indonesia.

3Department of Health Nutrition, Faculty of Medicine, Public Health and Nursing Universitas Gadjah Mada, Yogyakarta, Indonesia.

4Department of Food and Agricultural Product Technology, Faculty of Agricultural Technology, Universitas Gadjah Mada, Jl. Flora No 1 Bulaksumur, Yogyakarta, Indonesia.

5Center for Food and Nutrition Studies, Universitas Gadjah Mada, Jl. Teknika Utara Barek, Yogyakarta, Indonesia.

6Center of Excellence for Probiotics, Universitas Gadjah Mada, Jl. Teknika Utara Barek, Yogyakarta, Indonesia.

Corresponding Author Email: endangsrahayu@ugm.ac.id

DOI : https://dx.doi.org/10.12944/CRNFSJ.10.1.31

Article Publishing History

Received: 12 Mar 2021

Accepted: 19 Mar 2022

Published Online: 12 Apr 2022

Plagiarism Check: Yes

Reviewed by: Mukesh Sriwastva USA

Second Review by: Egbuonu Anthony Cemaluk Nigeria , Marlene Escobedo Monge Peru, Chile

Final Approval by: Prof. Gabriel O. Adegoke

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Abstract:

Synbiotics have a positive effect on the composition of the gut microbiota. They will increase the production of short-chain fatty acid that has modulating effect on gastrointestinal epithelial cell integrity, appetite regulation, and immune function. The aim of this study is to determine the effect of synbiotics (L. plantarum Dad-13 and fructo-oligosaccharide) on gut microbiota composition (L. plantarum, Bifidobacterium and Enterobacteriaceae) in stunting children under five in Yogyakarta, Indonesia. The research methods used double blind randomized controlled trials with parallel design. The sample consisted of 39 stunting children under five which was divided into 19 subjects as a synbiotic group given synbiotic (L. plantarum Dad-13 1x1010 CFU and fructo-oligosaccharide 700 mg) powder and 20 subjects as a placebo group given skim milk. The intervention was carried out for 90 days. The result showed that, statistically, there were significant differences in synbiotic group on gut microbiota (increased in L. plantarum and Bifidobacterium, while decreased in Enterobacteriaceae). Protein and carbohydrate were significantly increasing (p=0.000; p=0.001) in synbiotic group compared to placebo group. Body weight and height were significantly different (p=0.000) in both groups. Bodyweight and height of children on synbiotic group was increasing 1.02 and 1.6 times higher than placebo group. Neither morbidity nor weight loss was recorded throughout consumption period. Synbiotic powder has significantly positive effect on gut microbiota that can induce nutrient intake, height and weight gain of stunting children.

Keywords:

Height; Nutrient Intake; Weight

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Gunawan D. C. D, Juffrie M, Helmyati S, Rahayu E. S. Synbiotic (L. plantarum Dad-13 and Fructo-oligosaccharide) Powder on Gut Microbiota (L. plantarum, Bifidobacterium and Enterobacteriaceae) on Stunting Children in Yogyakarta, Indonesia.Curr Res Nutr Food Sci 2022; 10(1). doi : http://dx.doi.org/10.12944/CRNFSJ.10.1.31


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Gunawan D. C. D, Juffrie M, Helmyati S, Rahayu E. S. Synbiotic (L. plantarum Dad-13 and Fructo-oligosaccharide) Powder on Gut Microbiota (L. plantarum, Bifidobacterium and Enterobacteriaceae) on Stunting Children in Yogyakarta, Indonesia. Curr Res Nutr Food Sci 2022; 10(1). Available From: https://bit.ly/3jsPhgD


Introduction 

Stunting is a form of chronic undernutrition which is height-for-age z-score below -2 standard deviations according to WHO Child Growth Standards median.1 That occurs during critical periods of growth and development in early life. Children with poor nutrient intake have a higher risk of becoming stunted.3 Nowadays,  the concept of stunting has changed rapidly and has no longer been related to lack of nutrient intake, but it is related to the presence of gut microbiota like which can play a positive role in enhance nutrient absorption.4 Based on previous research, it shows that there is an disease that causes inflammation of the small intestine, namely Pediatric Environmental Enteropathy (PEE). PEE causes dysbiosis/imbalance in gut microbiota which is thought to be the main cause of in a group of children.5 A recent study in Bangladesh proved that infection with enteric bacteria, particularly Shigella and E. coli is associated with PEE in early in life.6 In stunted children, inflammatory genus such as Enterobacteriaceae is found which is also found in many inflammatory bowel patients. Whereas, healthy children had more probiotic species such as Lactobacillus and Bifidobacterium.7

Prevention of stunting is usually focused on improving nutrient, especially micronutrient .8 Based on previous study, it was reported that micronutrient intervention cannot prevent stunting.9,10,11,8 It is unfortunate that the prevalence of stunting cannot be reduced significantly using this method, especially in Indonesia.12 The 2018 Indonesian Basic Health Survey reported that around 30.8% of children under five years . Whereas in Yogyakarta, the percentage of stunting children under five years was 21.4% (15.1% stunted; 6.3% severely stunted), higher than the percentage of underweight that around 13%

Therefore, synbiotics are considered as an effective way to treat stunting in early life. Supplementation with synbiotics powder can increase the richness of gut microbiota. The gut microbiota plays an important role in the absorption of nutrients and accelerates the improvement of nutritional status to support growth and development on stunting children. Thus, this study aimed to determine the effect of on gut microbiota (L. plantarum, Bifidobacterium and Enterobacteriaceae) on stunting children.

Materials and Methods

Subject and Study Design 

It was conducted between January to May 2020 at Therapeutic Feeding Centre in Yogyakarta, Indonesia. The sample size was calculated using hypothesis testing for differences in 2 proportion between 2 independence groups. The minimal number of subjects required, with 95% confidence interval, power of 80% and 10% drop out into account. The inclusion criteria of the subject covered having height for age < -2SD, ranged between 12 – 59 months old, and did not take any probiotics in minimum month before the study took place or wash-in period. Figure 1 is a flow diagram showing the subject’s progression during this study period.

 Vol_10_No_1_Syni_Del_Fig1

Figure 1: Flow diagram of the progress through the phases of a parallel randomized trial of two groups (enrolment, intervention allocation, follow-up, and data analysis)

Click here to view Figure

 

Study Procedures

Total period of this study was 90 days. During the study period, the synbiotic group was given 1 g of synbiotic powder, while the placebo group was given 1 g of skim milk without synbiotic each day. Each participant’s representative was asked to fill compliance form to ensure the product was consumed daily.  The study product was a symbiotic powder containing L.plantarum Dad 13 1×1010 CFU and FOS 700 mg. L. plantarum Dad-13, indigenous probiotic strain was deposited in ampoules at the Food and Nutrition Culture Collection (FNCC), Center for Food and Nutrition Studies, Universitas Gadjah Mada. The FOS was obtained from PT. Beneo GmbH.

Fecal Sample Collection

Respondents were given a fecal kit box as a place to store fecal sample a day before fecal collection. The fecal kit box consists of fecal bottle, trail paper, rubber gloves, masks and ice gel. Ice gel contained in the stool kit box was previously frozen before being used. The ice gel serves to keep the fecal samples’ temperature cold.25 After the fecal collected, each sample was put into a sterile tube and mixed with 2 ml RNA-Later (Sigma-Aldrich;R0901; Saint Louis, MO, USA) than it was kept at freeze temperature (-180C  until -30 0C) immediately before it was used.26

Fecal microbiota populations with quantitative PCR (qPCR) DNA Extractions Protocol for Fecal Sample

DNA extraction was extracted from stool samples by using the bead-beating method.27  Immediately, RNA-later was diluted 10 fold (w/v) and washed with 1 ml of Phosphate-buffered saline (PBS), feces samples were mixed with 300 µL of Tris-Sodium dodecyl sulfate (SDS) solution and 500 µL of TE saturated phenol breaking the cell bead beater (FastPrep-24TM, MP Biomedials, USA) at a speed of 4000 rpm for 60 seconds. The supernatant obtained was added with 400 µL of phenol/ chloroform/isoamyl alcohol (25:24:1; v/v) (Sigma-Aldrich; P2069; Saint Louis, MO, USA) than bead beater (FastPrep -24TM, MP Biomedials, USA) for 30 seconds, followed by centrifugation at 13,000 rpm for 5 minutes at 40C. After centrifugation, 250 µL of the supernatant was mixed with 25 µL of 3 M sodium acetate (pH 5.2) (Sigma-Aldrich; 567422; Saint Louis, MO, USA) and incubated for 30 minutes on ice. Three hundred microliters of isopropanol were added and centrifuged at 13,000 rpm for 5 minutes at 4◦C. The DNA pellets were washed with 500 µL of cold ethanol 70% and shaken by hand and centrifuged at 13,000 rpm for 5 minutes at 40C. Removing the supernatant was by decantation than drying the pellets in the tube at room temperature for approximately one night. The last step was adding 20 µl buffer pH 8 and dissolving the pellets and then, keeping them at 1800C to 3000C.

Quantitative Real-Time PCR

The microbiota analysis stage used the quantitative real time PCR method including DNA dilution from the results of DNA isolation, making PCR master mix, reading, making standard curves, and calculating the results of the total number of bacteria.28  DNA dilution was carried out to equalize the concentration of DNA included in the PCR master mix mixture. The concentration of bacterial DNA was made to 20 ng/μL for L. plantarum, Bifidobacterium and Enterobacteriaceae.  The mastermix PCR was made every time you run PCR, consisted of a mixture of Eva Green (5 μL), forward primer (0.5 μL x 1000nM), reverse primer (0.5 μL x 1000nM), sample DNA (1 μL) and nuclease free water (3 μL). The real-time PCR tool used the Bio-Rad CFX-96. The results of multiplication and reading of bacterial DNA quantification were known using the analysis software Bio-Rad CFX Manager Software 3.0. The results of the analysis using the software showed the total L plantarum, Bifidobacterium and Enterobacteriaceae bacteria in the sample. Primers used had a DNA base sequence as shown in table 1.

Table 1: Primers.

Target Primer Sequence ( 5’ à 3’ )
Lactobacillus Plantarum28 sg-Lpla-F CTC TGG TAT TGA TTG GTG CTT GCA T
  sg-Lpla-R GTT CGC CAC TCA CTC AAA TGT AAA
Bifidobacterium29 g-Bifid-F CTC CTG GAA ACG GGT GG
  g-Bifid-R GGT GTT CTT CCC GAT ATC TAC A
Enterobacteriaceae30 En-Isu-3F TGC CGT AAC TTC GGG AGA AGG CA

En-Isu-3R

TCA AGG ACC AGT GTT CAG TGT C

Nutrient Intake

method. SQFFQ is a method to describe the individual nutrients intake habits at a certain as in use in time.31 period by interviewed mother of the children at Therapeutic Feeding Centre.  Nutrient intake was analyzed using NutriSurvey 2007 software based on subject’s SQFFQ. NutriSurvey is English translation of a professional German nutrition software (EBISpro).

Anthropometric Measurement

Measurement of weight was taken to the nearest of 0.1 kg, using a standardized 20 kg infant digital scale while measurement of height was taken to nearest of 0.1 cm, using measuring board for child under 2 years and microtoise for child over 2 years. Body weight and height were measured every month during consumption period. 

Data Analysis

Statistical analysis was performed in R program (v.4.0.3). A comparison between the group was analyzed using t-test. The data have a normal distribution based on Kolmogorov Smirnov analysis. Therefore, a comparison between the groups was analyzed using t-test and .  All analysis was performed on an intention to-treat basis where p-value< 0.05 was considered statistically significant.

Ethical Consideration

Parents or legal guardians were fully informed about the aim of the study, and they signed informed consent obtained from at least one parent or legal guardians because the subjects were minors. Protocol was approved by the Ethical Committee, Faculty of Medicine, Public Health and Nursing, Universitas Gadjah Mada, Yogyakarta, Indonesia. (Approval date: 25 November 2019; Ref. number: KE/FK/1388/EC/2019) The study was conducted in accordance with Declaration of Helsinki.

Results

There was no significant difference on synbiotic and placebo group (p>0.05), so it could be concluded that the subjects had the same characteristics at the baseline. Characteristics of research subjects including age, sex, weight, and height of children under five is shown in Table 2

Table 2: Baseline characteristic of subject.

Characteristics Synbiotic Group (n=19) Placebo Group (n=20) p
SexMaleFemale 127 137 0.905a
Age, month 26±8.34 29±5.78 0.194b
Weight, kg 8.5±0.94 9.0±0.82 0.103b
Height, cm 78.96±5.4 80.9±4.55 0.241b
a Chi-Square test, b Independent t-test, significant if p-value<0,05, Values are expressed as mean± SD.

Effect Consumption of Synbiotics Powder on L. plantarum, Bifidobacterium and Enterobacteriaceae

The difference in population of  L. plantarum, Bifidobacterium and Enterobacteriaceae was analyzed after consuming synbiotics powder for 90 days. There was a significant increase in the population of L.plantarum and Bifidobacteria and a significant decrease in the population of Enterobacteriaceae in the synbiotic group and not in the placebo group (Table 3). 

Table 3 : The difference between and within groups on L.plantarum, Bifidobacteria and Enterobacteriaceae.

   Synbiotic         groupMean±SD Placebo groupMean±SD p-valuea
L. plantarum
Before Intervention 4.36±0.33 4.34±0.34 0.876
After Intervention 5.70±0.26 4.38±0.31 0.000*
Bifidobacterium
Before Intervention 6.51±0.87 7.57±0.69 0.000*
After Intervention 7.85±0.66 7.34±0.63 0.017*
Enterobacteriaceae
Before Intervention 6.24±0.60 5.96±0.66 0.338
After Intervention 5.65±0.40 5.99±1.02 0.173

Data are presented as mean±SD, , aIndependent t-test

Energy, carbohydrate, protein intake in placebo group did not significant change after intervention (p>0.05) whereas, carbohydrate and protein intake in synbiotic group significantly changed after 90 days intervention (p<0.05)(Table 4).

Table 4: The difference of Nutrient Intake.

Group Before After p-value
Energy (Kcal) Synbiotic 984.07±253.96 1158±349.44 0.117
Placebo 1110.96±269.38 1202.42±197.91 0.165
Carbohydrate (g) Synbiotic 133.31±52.22 153.90±45.77 0.000*
Placebo 152.02±46.36 150.85±42.97 0.568
Proteins (g) Synbiotic 19.34±3.95 25.06±6.37 0.001*
Placebo 20.17±4.76 21.19±2.76 0.375
Fat (g) Synbiotic 36.37±6.37 40.20±10.83 0.455
Placebo 35.97±10.72 54.37±17.12 0.325

Data are presented as Mean±SD, *Independent sample t-test, a significantly different (p<0.05)

The mean of bodyweight gain in synbiotic group was 1.44±0.65 kg, from 8.53±0.92 to 9.97±1.34 kg while in placebo group was 0.78±0.62 kg, from 9.02±0.82 kg to 9.8±0.89 kg. Figure 2 shows the slope at synbiotic group was higher than placebo group, which was 0.083 and 0.081, consecutively. It showed that within 90 days of synbiotic consumption might be increase 0.083 kg of bodyweight every week and 0.081 kg in placebo group every week. Coefficient of determination ranges from 0 to 1 on both groups, it can be said that the effect of consuming synbiotic powder on body weight is large. This means that the model used is good to explain the effect of these variables. There was a significant difference in bodyweight after 90 days intervention on both groups (p-value<0.05) (table 5).

 Vol_10_No_1_Syni_Del_Fig2

Figure 2: Linear regression of weight in synbiotic and placebo group, y1 represents synbiotic group and y2 represents placebo group.

Click here to view Figure

 

The mean of height in synbiotic group was 3.89±0.80 cm, from 78.95±5.56 to 80.92±4.66 cm while in placebo group was 0.85±0.74 cm, from 80.92±4.66 cm to 83.43±4.52 cm. Figure 3 shows the slope at synbiotic group was 0.3375, greater than placebo group 0.2107. It means that every week of symbiotic consumption could increase 0.3375 cm in synbiotic group, while the height in placebo group increased 0.2107 cm every week. Coefficient of determination ranges from 0 to 1 on both groups, it can be said that the effect of consuming synbiotic powder on body weight is large. This means that the model used is good to explain the effect of these variables. There was a significant difference in height after 90 days intervention on both groups (p-value<0.05) (table 5).

 Vol_10_No_1_Syni_Del_Fig3

Figure 3: Linear regression of height in synbiotic and placebo group, y1 represents synbiotic group and y2 represents placebo group.

Click here to view Figure

 

Table 5: The difference of weight and height

Group Before After p-value
Weight (kg) Synbiotic group 8.53±0.97 9.96±1.41 0.000*
Placebo group 9.02±0.84 9.80±0.91 0.000*
Height (cm) Synbiotic group 78.95±5.56 83.08±5.56 0.000*
Placebo group 80.92±4.66 83.43±4.51 0.000*

Data are presented as mean±SD  *Independent sample t-test, a significantly different (p<0.05).

It would be a good idea to show children’s weight and height before this trial to compare if the growth rate has improved?

Tabel 6: Changes in Body Weight and Height

  Synbiotic group (Mean±SD) Placebo group (Mean±SD)
Baseline Day 30 Day 60 Day 90 Baseline Day 30 Day 60 Day 90
Weight (kg) 8.5±0.94 9.0±1.01 9.4±1.29 10.0±1.38 9.0±0.82 9.2±0.78 9.5±0.80 9.8±0.89
Height (cm) 78.9±5.48 80.5±5.86 81.7±5.38 83.1±5.42 80.9±4.55 81.7±4.50 82.7±4.45 83.4±4.40

 

Discussion

Based on real-time PCR analysis shown after 90 days intervention, the population of L. plantarum and Bifidobacterium increase significantly a significant decrease in the Enterobacteriaceae population. The increase of Bifidobacterium population could be resulted from increase in L. plantarum. In addition, the benefits of FOS, among others are to increase Bifidobacteria, Lactobacillus and to reduce Enterobacteriaceae and Clostridium perfringen. The increase in Bifidobacterium in the colon can have a positive impact on health. Bifidobacterium found in the colon helps maintaining health and is a bacterium that is much more important for life. The decrease or loss of Bifidobacterium in the human colon indicates that we are not healthy.32 In line with previous study, giving a synbiotic containing L. casei shirota (3 x 1010 CFU) and galacto-oligosaccharide (GOS) (2.5 g) for every 80 ml for 2 weeks can significantly increase Bifidobacterium.33 The increase in Bifidobacterium in the colon can have an impact positive for health. Bifidobacterium found in the colon helps in nourishing health and is a bacterium that is much more important to life. Decrease or loss of Bifidobacterium in the human colon is indicative that we are not well.34,32 low number of Bifidobacterium presents in malnutrition and inflammatory bowel syndrome patients. Overall there is a trend towards low levels of Bifidobacterium with various disease, so it plays a role in health.35 Lactobacillus and Bifidobacterium (which can decrease inflammation, strengthen gut barrier function, inhibit pathogens, and mediate other beneficial effects under certain conditions), are deficient in stool on undernourished children.

Conversely, the decreasing population of Enterobacteriaceae can cause inflammation or pathogens bacteria that can cause PEE.36  The previous study revealed that overall microbiota of stunted children were enriched in inflammogenic bacteria belonging to the Proteobacteria phylum, whereas those of children who were not stunted were enriched in probiotic species such as B. longum.37 The previous studies stating that 30 out of 30 healthy adult subjects experienced an increase in the population of L. plantarum after consuming the probiotic L. plantarum Dad-13 for 20 days. Previous research also stated that 20 out of 20 healthy adolescent subjects experienced an increase in the amount of L. plantarum (mean increase of 6.14 log 10 CFU/g of feces) after consuming the probiotic L. plantarum Dad-13 for 2 months. This shows that L. plantarum Dad-13 is able to live in the human gastrointestinal tract and has a beneficial impact on health. In line with previous research which states that L. plantarum Dad-13 is a strain that can survive in the digestive system, is resistant to bile salt and gastric juice, and is found in human feces who consume it.38 Subjects who experienced a decrease were higher than the increase in the population of the Enterobacteriaceae after drinking L. plantarum Dad-13 probiotics for 2 months, and it occurred in healthy adolescents in Yogyakarta, namely 11 out of 20 subjects that experienced a decrease in E. coli and 15 and 20 subjects that experienced a decrease in Coliform non E. coli.25 The consumption of L. plantarum Dad-13 for 20 days can reduce the Enterobacteriaceae population in 19 of 30 subjects (the average decrease is 0.71 log10 CFU/g of feces). This shows that it can reduce Enterobacteriaceae in the feces of some subjects. 39. Fecal microbial communities from both undernourished cohorts included increased proportions of pathogenic taxa within Proteobacteria, including Enterobacteriaceae, Escherichia, Klebsiella, and Shigella, as confirmed elsewhere.36,37 It should be noted that a similar pattern (increased proportions of Proteobacteria with decreased microbial diversity) is found in inflammatory bowel disease. On the other hand, genera containing potentially beneficial organisms are depleted in the undernourished gut.

Consumption 90 days of synbiotic powder significantly changes in nutrient intake especially protein and carbohydrate. In summary, synbiotic treatment for 90 days might have promotes protein and carbohydrate intake. The consumption of protein and carbohydrate is more than 70% RDA in Indonesia. Children in developing country typically consume plant-based diets rich in complex plant polysaccharides. In line with previous study, the consumption of gut microbiota in school-age children in Yogyakarta Indonesia and Khon Kaen Thailand was dominated by Prevotella bacteria (P-type) because of dominant intake in resistant starches.27 Conversely, fat intake tends to increase higher than the synbiotic group. This result was in line with previous studies stating that increasing consumption of high fat potentially increases the population of Enterobacteriaceae (inflammogenic bacteria).27,40 Stunting is closely related to food intake that is not sufficient for nutritional needs.41 Deficiencies in the intake of macro nutrients, especially energy and protein, as well as micronutrients contribute to this.42 Treatment with synbiotic powder for 90 days can be expected to increase nutrient intake on stunting children. In previous study, probiotic and prebiotic could increase bacterial deconjugation of bile acids and affect food intake. Low level of serum leptin can result increase in appetite that can make changes in food intake.43

In this study weight and height were significantly increasing after 90 days synbiotic treatment. Consumption of synbiotic (L. plantarum Dad-13 and FOS) group for 90 days may increase the bodyweight and height of children by 1.02 and 1.6 times higher than placebo group. It is line with the previous study stating that supplementation of E. faecium IS27526 at 108 cfu/day and 125 ml low fat milk for 90 days may increase the bodyweight of children by 1.5 times higher than supplementation of 125 ml low fat milk only.44  It might be due to the synergy between probiotics and prebiotics stimulate cell proliferation in order to expand the surface of mineral absorption thereby increasing mineral bioavailability so that facilitating better nutrient absorption, mostly of magnesium and calcium.45,46,47 Hence, the increasing on weight and height might be related to the role of synbiotic.

The main aim of prebiotics is to stimulate the growth and activity of beneficial bacteria in the gastrointestinal tract, which confers a health benefit on the host. Through mechanisms including antagonism (the production of antimicrobial substances) and competition for epithelial adhesion and nutrients, the intestinal microbiota acts as a barrier for pathogens. Final products of carbohydrate metabolism are mostly SCFAs, namely: acetic acid, butyric acid, and propionic acid, which are subsequently used by the host as a source of energy. 48 As a result of the fermentation of carbohydrates, Bifidobacterium or Lactobacillus may produce some compounds inhibiting the development of gastrointestinal pathogens, as well as causing a reduction in the intestinal pH.49 Moreover, Bifidobacterium demonstrates tolerance to the produced SCFAs and reduced pH. Therefore, due to their favorable effect on the development of beneficial intestinal bacteria, the administration of prebiotics may participate in the inhibition of the development of pathogens. SCFAs are a subset of fatty acids that are produced by the gut microbiota during the fermentation of partially and non-digestible polysaccharides 50. Diet composition and intake (e.g., types of fibers and iron) have been reported to influence the microbiota composition and the gut SCFA concentration and to impact gut motility and to strengthen the gut barrier functions. SCFAs are estimated to contribute 6%–10% of total energy requirements, and the contribution is expected to be higher for humans consuming high-fiber diets and for herbivorous species.51

Efficient energy metabolism requires communication between the gut and peripheral organs such as the pancreas, liver, adipose tissue, and brain. Information about nutritional status in the gut is relayed by various signals, including gut derived hormones such as glucagon-like peptide-1 (GLP-1). Transient postprandial increases in GLP-1 have many effects on metabolism, including the stimulation of insulin secretion (incretin effect), inhibition of gastric emptying, and an increased feeling of satiety. Secretion of GLP-1 from enteroendocrine L cells can be stimulated by sugars, amino acids, and long-chain fatty acids. Dietary supplementation with fermentable fibers has been shown to increase GLP-1 levels in rodents and humans and SCFAs can stimulate GLP-1 secretion in vitro. Thus, it has been suggested that the gut microbiota increases GLP-1 levels through the production of SCFAs. The absence of SCFAs-producing microbes in GF colon results in significantly higher plasma GLP-1 levels. This colonic-derived GLP-1 has an important role in slowing small intestinal transit, which may be an adaptive response for promoting nutrient absorption.52 It can impact to increase in body weight and height. Synbiotic treatment for 90 days is able nourish gut microbiota than can give a positive effect on nutrient intake and anthropometric parameters (weight and height) on stunting children

Conclusion

Consumption synbiotic (L. plantarum Dad-13 and fructo-oligosaccharide) powder for 90 days was significant in gut microbiota composition (increasing on population of L. plantarum and Bifidobacterium; decreasing on population of Enterobacteriaceae). In addition, it is also significant in nutrient intake such as protein and carbohydrates. Synbiotic also may increase the bodyweight and height of children by 1.02 and 1.6 times higher than placebo group.

Funding Sources 

This study was supported by Program Rekognisi Tugas Akhir (RTA) 2020 Universitas Gadjah Mada (732/UN1.P.III/KPT/HUKOR/2020).

Acknowledgement

We are grateful to Food and Nutrition Culture Collection (FNCC), Center for Food and Nutrition Studies, Universitas Gadjah Mada for supplying L. plantarum Dad-13 for this study. We also thanks to Therapeutic Feeding Centre Yogyakarta where the study was carried out and last but not least thank the participating parents and their children who volunteered for the study.

Conflict of Interest

All authors report that there is no conflict of interest.

Funding Sources

There is no funding source.

References

  1. WHO. Reducing Stunting In Children.; 2018. https://apps.who.int/iris/bitstream/handle/10665/260202/9789241513647-eng.pdf?sequence=1
  2. Dewey KG, Begum K. Long-term consequences of stunting in early life. Matern Child Nutr. Published online 2011. doi:10.1111/j.1740-8709.2011.00349.x
    CrossRef
  3. Habimana S, Biracyaza E. Risk Factors Of Stunting Among Children Under 5 Years Of Age In The Eastern And Western Provinces Of Rwanda: Analysis Of Rwanda Demographic And Health Survey 2014/2015. Pediatr Heal Med Ther. 2019;Volume 10:115-130. doi:10.2147/phmt.s222198
    CrossRef
  4. Pekmez CT, Dragsted LO, Brahe LK. Gut microbiota alterations and dietary modulation in childhood malnutrition – The role of short chain fatty acids. Clin Nutr. 2019;38(2):615-630. doi:10.1016/j.clnu.2018.02.014
    CrossRef
  5. Vonaesch P, Randremanana R, Gody JC, et al. Identifying the etiology and pathophysiology underlying stunting and environmental enteropathy: Study protocol of the AFRIBIOTA project. BMC Pediatr. 2018;18(1). doi:10.1186/s12887-018-1189-5
    CrossRef
  6. Monira S, Nakamura S, Gotoh K, et al. Gut microbiota of healthy and malnourished children in Bangladesh. Front Microbiol. 2011;2(NOV):1-7. doi:10.3389/fmicb.2011.00228
    CrossRef
  7. Gordon JI, Dewey KG, Mills DA, Medzhitov RM. The human gut microbiota and undernutrition. Sci Transl Med. 2012;4(137):2-7. doi:10.1126/scitranslmed.3004347
    CrossRef
  8. Penny ME dit. Micronutrients in the treatment of stunting and moderate malnutrition. Nestle Nutr Inst Workshop Ser. 2012;70:11-21. doi:10.1159/000337388
    CrossRef
  9. Semba RD, Trehan I, Gonzalez-Freire M, et al. Perspective: The Potential Role of Essential Amino Acids and the Mechanistic Target of Rapamycin Complex 1 (mTORC1) Pathway in the Pathogenesis of Child Stunting. Adv Nutr. 2016;7(5):853-865. doi:10.3945/an.116.013276
    CrossRef
  10. Goudet SM, Bogin BA, Madise NJ, Griffiths PL. Nutritional interventions for preventing stunting in children (Birth to 59 months) living in urban slums in low-and middle-income countries (LMIC). Cochrane Database Syst Rev. 2019;2019(6). doi:10.1002/14651858.CD011695.pub2
    CrossRef
  11. Hemalatha R, Ouwehand AC, Saarinen MT, Prasad U V., Swetha K, Bhaskar V. Effect of probiotic supplementation on total lactobacilli, bifidobacteria and short chain fatty acids in 2–5-year-old children. Microb Ecol Health Dis. 2017;28(1):1298340. doi:10.1080/16512235.2017.1298340
    CrossRef
  12. Badan Penelitian dan Pengembangan Kesehatan. Laporan_Nasional_RKD2018_FINAL.pdf. Badan Penelit dan Pengemb Kesehat. Published online 2018:198. http://labdata.litbang.kemkes.go.id/images/download/laporan/RKD/2018/Laporan_
    Nasional_RKD2018_FINAL.pdf
  13. Riskesdas K. Hasil Utama Riset Kesehata Dasar (RISKESDAS). J Phys A Math Theor. 2018;44(8):1-200. doi:10.1088/1751-8113/44/8/085201
    CrossRef
  14. De Preter V, Hamer HM, Windey K, Verbeke K. The impact of pre- and/or probiotics on human colonic metabolism: Does it affect human health? Mol Nutr Food Res. 2011;55(1):46-57. doi:10.1002/mnfr.201000451
    CrossRef
  15. Rahayu ES, Yogeswara A, Mariyatun, Windiarti L, Utami T, Watanabe K. Molecular characteristics of indigenous probiotic strains from Indonesia. Int J Probiotics Prebiotics. 2016;11(2):109-116.
  16. Bryk G, Coronel MZ, Pellegrini G, et al. Effect of a combination GOS/FOS® prebiotic mixture and interaction with calcium intake on mineral absorption and bone parameters in growing rats. Eur J Nutr. Published online 2015. doi:10.1007/s00394-014-0768-y
    CrossRef
  17. Pérez-Conesa D, López G, Abellán P, Ros G. Bioavailability of calcium, magnesium and phosphorus in rats fed probiotic, prebiotic and synbiotic powder follow-up infant formulas and their effect on physiological and nutritional parameters. J Sci Food Agric. Published online 2006. doi:10.1002/jsfa.2618
    CrossRef
  18. Vrese M De. Probiotics, prebiotics, and synbiotics—approaching a definition 1–3. 2001;73(14).
  19. Petreska Ivanovska T, Jurhar Pavlova M, Mladenovska K, Petrushevska-Tozi L. Probiotics, prebiotics, synbiotics in prevention and treatment of inflammatory bowel diseases. Maced Pharm Bull. 2014;60(02):3-19. doi:10.33320/maced.pharm.bull.2014.60.02.001
    CrossRef
  20. Martin-Gallausiaux C, Marinelli L, Blottière HM, Larraufie P, Lapaque N. SCFA: Mechanisms and functional importance in the gut. Proc Nutr Soc. 2020;(December 2019). doi:10.1017/S0029665120006916
    CrossRef
  21. Hijova E, Chmelarova A. Short Chain Fatty Acids and Intestinal Microflora. 2006;(February):3-6.
    CrossRef
  22. Ríos-Covián D, Ruas-Madiedo P, Margolles A, Gueimonde M, De los Reyes-Gavilán CG, Salazar N. Intestinal short chain fatty acids and their link with diet and human health. Front Microbiol. 2016;7(FEB):1-9. doi:10.3389/fmicb.2016.00185
    CrossRef
  23. Den Besten G, Van Eunen K, Groen AK, Venema K, Reijngoud DJ, Bakker BM. The role of short-chain fatty acids in the interplay between diet, gut microbiota, and host energy metabolism. J Lipid Res. 2013;54(9):2325-2340. doi:10.1194/jlr.R036012
    CrossRef
  24. Nagpal R, Wang S, Ahmadi S, et al. Human-origin probiotic cocktail increases short-chain fatty acid production via modulation of mice and human gut microbiome. Sci Rep. 2018;8(1):1-15. doi:10.1038/s41598-018-30114-4
    CrossRef
  25. Maghfirotin Marta B, Tyas U, Muhammad Nur C, Jaka W, Endang Sutriswati R.  Effects of Consumption of Probiotic Powder Containing Lactobacillus Plantarum Dad-13 on Fecal Bacterial Population in School-Age Children in Indonesia . Int J Probiotics Prebiotics. 2019;14(1):1-8. doi:10.37290/ijpp2641-7197.14:1-8
    CrossRef
  26. Kamil RZ, Murdiati A, Juffrie M, Nakayama J, Rahayu ES. Gut microbiota and short-chain fatty acid profile between normal and moderate malnutrition children in Yogyakarta, Indonesia. Microorganisms. 2021;9(1):1-15. doi:10.3390/microorganisms9010127
    CrossRef
  27. Nakayama J, Watanabe K, Jiang J, et al. Diversity in gut bacterial community of school-age children in Asia. Sci Rep. 2015;5:1-12. doi:10.1038/srep08397
    CrossRef
  28. Matsuda K, Tsuji H, Asahara T, Matsumoto K, Takada T, Nomoto K. Establishment of an analytical system for the human fecal microbiota, based on reverse transcription-quantitative PCR targeting of multicopy rRNA molecules. Appl Environ Microbiol. 2009;75(7):1961-1969. doi:10.1128/AEM.01843-08
    CrossRef
  29. Matsuki T, Watanabe K, Fujimoto J, et al. Development of 16S rRNA-gene-targeted group-specific primers for the detection and identification of predominant bacteria in human feces. Appl Environ Microbiol. 2002;68(11):5445-5451. doi:10.1128/AEM.68.11.5445-5451.2002
    CrossRef
  30. Matsuda K, Tsuji H, Asahara T, Kado Y, Nomoto K. Sensitive quantitative detection of commensal bacteria by rRNA-targeted reverse transcription-PCR. Appl Environ Microbiol. 2007;73(1):32-39. doi:10.1128/AEM.01224-06
    CrossRef
  31. Tang Y, Liu Y, Xu L, et al. Validity and reproducibility of a revised semi-quantitative food frequency questionnaire (SQFFQ) for women of age-group 12-44 years in Chengdu. J Heal Popul Nutr. 2015;33(1):50-59. doi:10.3329/jhpn.v33i1.3194
  32. Mitsuoka T. Establishment of intestinal bacteriology. Biosci Microbiota, Food Heal. 2014;33(3):99-116. doi:10.12938/bmfh.33.99
    CrossRef
  33. Matsumoto K, Takada T, Shimizu K, et al. The Effects of a Probiotic Milk Product Containing Lactobacillus casei Strain Shirota on the Defecation Frequency and the Intestinal Microflora of Sub-optimal Health State Volunteers: A Randomized Placebo-controlled Cross-over Study. Biosci Microflora. 2006;25(2):39-48. doi:10.12938/bifidus.25.39
    CrossRef
  34. Arboleya S, Watkins C, Stanton C, Ross RP. Gut bifidobacteria populations in human health and aging. Front Microbiol. 2016;7(AUG):1-9. doi:10.3389/fmicb.2016.01204
    CrossRef
  35. Taverniti V, Guglielmetti S. Methodological issues in the study of intestinal microbiota in irritable bowel syndrome. World J Gastroenterol. 2014;20(27):8821-8836. doi:10.3748/wjg.v20.i27.8821
  36. Ghosh TS, Gupta S Sen, Bhattacharya T, et al. Gut microbiomes of Indian children of varying nutritional status. PLoS One. 2014;9(4):1-13. doi:10.1371/journal.pone.0095547
    CrossRef
  37. Dinh DM, Ramadass B, Kattula D, et al. Longitudinal analysis of the intestinal microbiota in persistently stunted young children in south India. PLoS One. Published online 2016. doi:10.1371/journal.pone.0155405
    CrossRef
  38. Dolly P, Anishaparvin A, Joseph GS, Anandharamakrishnan C. Microencapsulation of Lactobacillus plantarum (mtcc 5422) by spray-freeze-drying method and evaluation of survival in simulated gastrointestinal conditions. J Microencapsul. Published online 2011. doi:10.3109/02652048.2011.599435
    CrossRef
  39. Liwan SY, Utami T, Murdiati A, Triwitono P, Rahayu ES. Dietary patterns and effect of consumption of probiotic powder containing indigenous bacteria Lactobacillus plantarum Dad-13 on Streptococcus, Enterococcus, Escherichia coli and Klebsiella pneumoniae in the gut of students at Junior High School Pangururan. Int Food Res J. 2020;27(5):790-797.
  40. Nakayama J, Yamamoto A, Palermo-Conde LA, et al. Impact of westernized diet on gut microbiota in children on Leyte island. Front Microbiol. 2017;8(FEB):1-18. doi:10.3389/fmicb.2017.00197
    CrossRef
  41. Bardosono S, Dewi LE, Sukmaniah S, Permadhi I, Eka AD, Lestarina L. Effect of a six-month iron-zinc fortified milk supplementation on nutritional status, physical capacity and speed learning process in Indonesian underweight schoolchildren: Randomized, placebo-controlled. Med J Indones. 2009;18(3):193-202. doi:10.13181/mji.v18i3.361
    CrossRef
  42. Blaney S, Februhartanty J, Sukotjo S. Feeding practices among Indonesian children above six months of age: A literature review on their potential determinants (part 2). Asia Pac J Clin Nutr. 2015;24(1):28-37. doi:10.6133/apjcn.2015.24.1.14
  43. Hosseinifard E-S, Bavafa-Valenlia K, Saghafi-Asl M, Morshedi M.  Antioxidative and Metabolic Effects of Lactobacillus plantarum , Inulin, and Their Synbiotic on the Hypothalamus and Serum of Healthy Rats . Nutr Metab Insights. 2020;13:117863882092509. doi:10.1177/1178638820925092
    CrossRef
  44. Surono IS, Koestomo FP, Novitasari N, Zakaria FR, Yulianasari, Koesnandar. Novel probiotic Enterococcus faecium IS-27526 supplementation increased total salivary sIgA level and bodyweight of pre-school children: A pilot study. Anaerobe. 2011;17(6):496-500. doi:10.1016/j.anaerobe.2011.06.003
    CrossRef
  45. Parvaneh K, Jamaluddin R, Karimi G, Erfani R. Effect of probiotics supplementation on bone mineral content and bone mass density. Sci World J. Published online 2014. doi:10.1155/2014/595962
    CrossRef
  46. Kurniasari Y, Juffrie M, Jamil MD. Kadar kalsium serum pada anak stunting dan tidak stunting usia 24-59 bulan. J Gizi Klin Indones. 2016;12(3):108-115.
    CrossRef
  47. Whisner CM, Castillo LF. Prebiotics, Bone and Mineral Metabolism. Calcif Tissue Int. Published online 2018. doi:10.1007/s00223-017-0339-3
    CrossRef
  48. Grajek W, Olejnik A, Sip A. Probiotics, prebiotics and antioxidants as functional foods. Acta Biochim Pol. 2005;52(3):665-671. doi:10.18388/abp.2005_3428
    CrossRef
  49. Gibson GR, Wang X. Regulatory Effects of the Growth of Bifidobacteria on Other Large Intestinal Microorganisms. J Appl Bacteriol. 1994;77(4):412-420. https://doi.org/10.1111/j.1365-2672.1994.tb03443.x
    CrossRef
  50. Tan J, McKenzie C, Potamitis M, Thorburn AN, Mackay CR, Macia L. The Role of Short-Chain Fatty Acids in Health and Disease. Vol 121. 1st ed. Elsevier Inc.; 2014. doi:10.1016/B978-0-12-800100-4.00003-9
    CrossRef
  51. Morrison DJ, Preston T. Formation of short chain fatty acids by the gut microbiota and their impact on human metabolism. Gut Microbes. 2016;7(3):189-200. doi:10.1080/19490976.2015.1134082
    CrossRef
  52. Yan J, Herzog JW, Tsang K, et al. Gut microbiota induce IGF-1 and promote bone formation and growth. Proc Natl Acad Sci. Published online 2016. doi:10.1073/pnas.1607235113
    CrossRef


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