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Effect of multifibre mixture with prebiotic components on bifidobacteria and stool pH in tube-fed children

Published online by Cambridge University Press:  06 August 2010

Dominique Guimber*
Affiliation:
Unité de Nutrition Artificielle à Domicile, CHU Lille, Lille, France Clinique de Pédiatrie, Hôpital Jeanne de Flandre, CHRU de Lille, 59 037Lille cedex, France
Béatrice Bourgois
Affiliation:
CIC-9301-CHRU-Inserm de Lille, IFR 114, IMPRT & CHRU de Lille, Lille, France
Laurent Beghin
Affiliation:
CIC-9301-CHRU-Inserm de Lille, IFR 114, IMPRT & CHRU de Lille, Lille, France EA-3925, IFR 114, Université Faculté de Médecine, Lille 2, Lille, France
Sébastien Neuville
Affiliation:
Unité de Nutrition Artificielle à Domicile, CHU Lille, Lille, France
Philippe Pernes
Affiliation:
Centre Antoine de St Exupéry, Vendin le Vieil, France
Kaouther Ben Amor
Affiliation:
Nutricia Advanced Medical Nutrition, Danone Research – Centre for Specialised Nutrition, Wageningen, The Netherlands
Annemiek Goedhart
Affiliation:
Nutricia Advanced Medical Nutrition, Danone Research – Centre for Specialised Nutrition, Wageningen, The Netherlands
John Sijben
Affiliation:
Nutricia Advanced Medical Nutrition, Danone Research – Centre for Specialised Nutrition, Wageningen, The Netherlands
Jan Knol
Affiliation:
Nutricia Advanced Medical Nutrition, Danone Research – Centre for Specialised Nutrition, Wageningen, The Netherlands
Frédéric Gottrand
Affiliation:
Unité de Nutrition Artificielle à Domicile, CHU Lille, Lille, France EA-3925, IFR 114, Université Faculté de Médecine, Lille 2, Lille, France
*
*Corresponding author: D. Guimber, fax +33 320445963, email [email protected]
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Abstract

The objective of the present study was to evaluate the effect of a paediatric tube feed supplemented with a multifibre mixture on the gut microbiota and nutritional and micronutrient status of children on long-term enteral nutrition (EN). A randomised, controlled, double-blind, cross-over trial (2 × 3 months) with a washout period of 1 month was carried out. Twenty-seven children (80 % neurologically impaired) aged 11·9 (sd 3·9) years, on long-term EN (4·8 (sd 3·9) years) were recruited. The analyses of the children's faecal pH, microbiota along with anthropometric measures, bowel movements and markers of blood micronutrient status were made. Twenty children completed the study. A significant increase in the proportion of stool bifidobacteria (+16·6 %, P < 0·05) was observed during the multifibre period than during the fibre-free period, together with a significant reduction in stool pH (P < 0·001). Stool frequency and consistency as well as growth did not differ between the two periods. There was a significant increase (P < 0·05) in plasma ferritin at the end of the fibre-free period, but plasma ferritin levels remained within normal ranges during both periods. No diet effects on other blood parameters were observed. In conclusion, addition of a multifibre mixture with prebiotic components to paediatric EN is well tolerated, promotes bifidobacteria and reduces stool pH, indicating an improved gut health.

Type
Full Papers
Copyright
Copyright © The Authors 2010

Paediatric indications for enteral nutrition (EN) have increased along with the increasing recognition of the clinical efficacy of nutritional support in treating the most severe and chronic diseases in childhood(Reference Daveluy, Guimber and Mention1). The long duration of EN, which is explained by the increased life expectancy of children with chronic diseases (e.g. cystic fibrosis and neurological disabilities) requiring home EN, reinforces the need to use EN products closely adapted to the children's needs. EN is intended to provide the individual with all the nutrients necessary for maintaining the optimal growth and development. Depending on the child's age, anthropometry, growth rate and pathology, EN formulas can have energy densities ranging from 3·1 kJ/ml (0·75 kcal/ml) to 6·3 kJ/ml (1·5 kcal/ml). Enteral formulas for paediatric patients also vary in the proportion of nutrients they contain to address patient-specific requirements. Although most of the paediatric EN are nutritionally complete, many do not contain fibre.

The health benefits of dietary fibre have been well described and have formed the basis of dietary recommendations for children and adults(Reference Lunn and Buttriss2, Reference Alexy, Kersting and Sichert-Hellert3). Dietary fibre is important to maintain gastrointestinal (GI) health and may, in addition, reduce the risk of CHD(Reference Lunn and Buttriss2, Reference Williams4, Reference Marlett, McBurney and Slavin5). Recommendations for daily fibre intake in healthy children are primarily based on the extrapolation of data from adults(Reference Alexy, Kersting and Sichert-Hellert3, Reference Edwards and Parrett6), and are mostly expressed on a body weight, age or energy intake basis(Reference Lunn and Buttriss2Reference Williams4).

Because dietary fibre has important GI health benefits in childhood, especially in normalising bowel function, fibre-supplemented feeds may be beneficial for children with diarrhoea and constipation(Reference Lunn and Buttriss2, Reference Williams4, Reference Marlett, McBurney and Slavin5, Reference Marlett, McBurney and Slavin7). Diarrhoea and constipation, representing the two extremes of bowel function, remain the most frequent problems associated with EN in children. Diarrhoea is regularly reported in critically ill children(Reference López-Herce, Santiago and Sánchez8, Reference Sánchez, López-Herce and Carrillo9), whereas constipation is more common in the chronic-care setting, especially in children with neurodisabilities. About 60–75 % of children with neurological impairments have been reported to suffer from constipation(Reference Sullivan, Lambert and Rose10, Reference Del Giudice, Staiano and Capano11). However, there are only limited data available on the role, tolerability and efficacy of fibre-supplemented enteral formulas in children(Reference Tolia, Ventimiglia and Kuhns12Reference Elia, Engfer and Green15), and the effect of fibre supplementation on gut microbiota has not been investigated as yet.

Therefore, the objective of the present study was to evaluate the effect of a paediatric tube feed supplemented with a multifibre mixture on the gut microbiota, bowel function, GI tolerance and nutritional and micronutrient status of children over 7 years of age on long-term EN.

Subjects and methods

Subjects

The present study was a randomised, controlled, double-blind, cross-over trial comparing a standard, fibre-free paediatric tube feed to a multifibre-enriched feed in enterally fed children. Children fed enterally for at least 2 weeks, with a stable condition and nutritional intake, and requiring EN for a minimum of 8 months were recruited at the Centre Hospitalier Régional Universitaire de Lille (France) and affiliated healthcare centre of Vendin Le-Viel (France) between September 2003 and December 2005.

Children were deemed eligible for inclusion in the study if they were at least 7 years old, had a body weight >21 kg, had a stable medical condition and a stable intake of EN contributing at least 50 % of their total energy intake, and had not received a fibre-supplemented enteral formula for at least 2 weeks before inclusion. Eligible children also had to consume less than two servings of yoghurts or fermented products per day, and to have an oral fibre intake < 1 g/d. Exclusion criteria were cow's milk allergy, inflammatory bowel disease, bowel resection, other diseases associated with GI disorders and dyslipoproteinaemia. Further exclusion criteria included antibiotic therapy or use of laxatives other than polyethylene glycol or paraffin oil during the 2 weeks preceding the study, acute diarrhoea during the 2 weeks preceding the study and supplementation with Fe and/or any of the other monitored micronutrients during the month before inclusion. Written informed consent was obtained from both parents of every eligible child. The protocol was approved by the ethics committee (Comité Consultatif de Protection des Personnes se prêtant à la Recherche Biomédicale, Lille, France).

Study design

The study products used were manufactured and distributed by Nutricia N.V., Zoetermeer, The Netherlands. Tentrini® and Tentrini® Energy (also known as NutriniMax® and NutriniMax® Energy; both referred to as TEN in the present study) are nutritionally complete, fibre-free paediatric tube feeds for children aged 7–12 years or 21–45 kg in weight, providing 4·2 kJ/ml (1 kcal/ml) and 6·3 kJ/ml (1·5 kcal/ml) of feed, respectively (Table 1). Tentrini® Multi Fibre and Tentrini® Energy Multi Fibre (also known as NutriniMax® Multi Fibre and NutriniMax® Energy Multi Fibre; both referred to as TMF) are similar in composition to Tentrini and Tentrini Energy, but provide 1·1 g/100 ml of a mixed fibre source (Table 1). The Multi Fibre mixture (MF6™) consists of fructo-oligosaccharides (10·3 %), inulin (22·2 %), soya polysaccharides (30·1 %), cellulose (11·3 %), gum arabic (15·0 %) and resistant starch (11·1 %). The choice for a standard or energy-enriched paediatric feed was dependent on the energy needs of the child. Children receiving a fibre-containing enteral feed before the study were allocated to a fibre-free feed during a run-in period of 1 month before the first phase of the study.

Table 1 Nutritional composition of the paediatric study formulas per 100 ml

RE, retinol equivalent; α-TE, tocopherol equivalent.

All children were then randomised (following a computer-generated randomisation list) to start the study intervention period on either one of the paediatric feeds supplemented with the Multi Fibre mixture (TMF) or one of the control feeds without fibre (TEN) for the first phase of 3 months. For the second phase, children were switched to the other study feeds. Between the two intervention phases, all children followed a washout period of 1 month on TEN.

Assessments were made at the beginning and end of each study phase (at the start of the study, and after 3, 4 and 7 months).

Dietary intake

As the children had a stable medical condition and a stable intake of EN before the study, energy intake from tube feeding was assumed to be constant during the entire study period. The daily energy intake from tube feeding during the study period was estimated by multiplying the reported volume consumed at baseline by the energy content of the study feed received during each phase. At each visit, a 48 h dietary recall (recording all foods and drinks consumed orally over the previous 2 d) was completed. From these data, the daily energy intake from the oral diet was estimated. Twenty of twenty-seven patients had no oral intake and for the seven patients who continued to eat, oral food intake remained limited. Overall, the EN amounted for 80–85 % of the total energy intake of the patients. Compliance was not directly monitored in the present study, but the study product was delivered on a monthly basis by the centre to the patient's house as a method of accountability.

Concomitant medication

Any changes in the medication prescribed or therapeutic procedures carried out on the child were recorded at each visit. Except for antibiotics that were adapted to the clinical situation of the patient, care was taken that the medical treatment (anticonvulsive drugs and laxatives) remained the same during the two phases of the study.

Anthropometry

Children were weighed and measured for height and mid-upper arm circumference at each visit (at the start of the study and after 3, 4 and 7 months of intervention). Skinfold thickness was also measured at these visits (three measures at four sites (biceps, triceps, sub-scapular and supra-iliac)) on the left side of the body using Holtain calipers(Reference Durnin and Womersley16). Bioelectrical impedance absorptiometry (BIA) was carried out for each child at the same time points. Fat mass (FM) was quantified using skinfold thickness measurements and using either Brook's equation(Reference Brook17) for children aged 7–11 years or Durnin & Rahaman's equation(Reference Durnin and Rahaman18) for children aged >12 years. Siri's equation(Reference Siri19) was then used to calculate the percentage of FM. Fat-free mass (FFM) was determined by BIA using Schaefer's equation(Reference Schaefer, Georgi and Zieger20). The percentages of FM and FFM were obtained by averaging the results of both methods (skinfold and BIA).

Bowel movements and gastrointestinal symptoms

Parents were requested to record stool frequency and consistency (0: hard; 1: normal; 2: soft; and 3: liquid) during the 15 d preceding each visit to the clinic. During the same periods, GI symptoms (belching, flatulence, bloating, nausea, vomiting and abdominal pain) were also reported by the parents and rated for their severity (0: absent; 1: light; 2: moderate; or 3: severe) in order to assess tolerance.

Faecal microbiology, pH and SCFA

In the week preceding each visit (at the start of the study and after 3, 4 and 7 months), parents were asked to collect a fresh stool sample immediately after defaecation. In the event that antibiotic treatment was used during the course of the study, the faecal sample was collected before the start of antibiotic therapy or otherwise delayed to 15 d following the end of the medication. Samples were immediately stored at − 20°C until further processing. For each faecal sample, pH and DM were determined. Quantification of distinct groups of bacteria was performed using the fluorescent in situ hybridisation(Reference Langendijk, Schut and Gijsbert21). Specific bacteria were stained with Cy3-labelled 16S rRNA-targeted oligonucleotides (Bif164 for bifidobacteria(Reference Langendijk, Schut and Gijsbert21), Lab158 for lactobacilli(Reference Harmsen, Gibson and Elfferich22), Ec1531 for Escherichia coli (Reference Poulsen, Lan and Kristensen23) and Chis150 and Clit135 for subgroups of clostridia(Reference Franks, Harmsen and Raangs24)), and the absolute numbers of bacteria per gram faeces were obtained by counterstaining with the DNA-binding dye 4′,6-diamidino-2-phenylindole(Reference Thiel and Blaut25). The oligonucleotide probes used in the present study, their sequence and their targeted micro-organisms are given in Table 2. Hybridisation and washing steps were performed according to the conditions described in the cited references, except for the Ec1531 probe for which no formamide was used, and the samples were hybridised at 50°C instead of at 37°C.

Table 2 List of the 16S rRNA-targeted oligonucleotides used in the present study

*  The hybridisation and washing conditions for this probe were modified as follows: the hybridisation buffer contained 0·9 m-NaCl, 20 mm-Tris–HCl (pH 7·2), and 0·1 % (w/v) SDS and no formamide was used. The hybridisation and washing temperature was set to 50°C.

 The Clit135 and Chis150 probes were used in combination.

Faecal samples were thawed, and the pH was measured directly at room temperature using a Handylab pH meter (Schott Glas, Mainz, Germany) equipped with an Inlab 423 pH electrode (Mettler-Toledo, Columbus, OH, USA).

Acetic, propionic, n-butyric, iso-butyric and n-valeric acids were quantitatively determined by a Varian 3800 GC (Varian, Inc., Walnut Creek, CA, USA) equipped with a flame ionisation detector as described previously(Reference Knol, Scholtens and Kafka26).

Micronutrients

Blood samples were collected at the beginning and end of each phase (0, 3, 4 and 7 months), and were analysed in the same laboratory. Hb, mean corpuscular volume and ferritin were analysed using standard methods. Plasma vitamin E was determined by HPLC(Reference MacCrehan and Schönberger27). Vitamin C was determined with an automated enzymatic procedure, (Reference Lee, Roberts and Labbe28) and all the samples were analysed within 1 h. Se was analysed by inductively coupled plasma-MS. Zn was analysed by flame atomic absorption spectrometry. Glutathione peroxidase concentration was analysed using a RANSEL kit (Randox Limited, Crumlin, County Antrim, UK) following the method of Paglia and Valentine(Reference Paglia and Valentine29), and superoxide dismutase was analysed using a RANSOD kit (Randox Limited) following the method described by Mac Cord & Fridovich(Reference McCord and Fridovich30), both of which were then adapted to a Hitachi 911 (Roche, Meylan, France) spectrophotometer.

Statistical analysis

Baseline characteristics of the children were analysed as frequency and descriptive data. Outcome variables were analysed on the basis of intention to treat. Normality was assumed for the Shapiro–Wilk test with P>0·05. Differences in continuous variables were expressed as mean with standard error or mean and standard deviation when the data were normally distributed and compared between groups using the Student t test. For non-parametric data, values were expressed as median (range) and compared using the Mann–Whitney U-test. The statistical model took into account the treatment, period and carry-over effects as described by Altman(Reference Altman31). All data analyses were done using Statistical Package for the Social Sciences 12.0.1 version for Windows (SPSS, Inc., Chicago, IL, USA). Statistical significance was set at P < 0·05.

Results

Twenty-seven children, of whom twenty-two had neurodisabilities, were recruited between September 2003 and June 2005. Twenty children completed the study (eighteen had neurodisabilities), with seven early terminations that included abdominal surgery because of a digestive fistula post gastrostomy, two consent withdrawals, three disturbed GI functions with diarrhoea and one loss to follow-up.

Baseline characteristics of the children are presented in Table 3. All children were fed via gastrostomy. Interpretable 48 h recalls were collected for nine patients at visit 1, seven patients at visit 2, six patients at visit 3 and five patients at visit 4. Oral energy intake as assessed by these dietary recalls was, on average, 1912·1 kJ/d (457 kcal/d) at visit 1, 2267·7 kJ/d (542 kcal/d) at visit 2, 2606·6 kJ/d (623 kcal/d) at visit 3 and 3092 kJ/d (739 kcal/d) at visit 4. Seventeen subjects required the high-energy version of the study feed, eight subjects required the standard energy version and two subjects needed a combination of both densities. During the TMF phase, children consumed an estimated 8·4 (sd 2·2) g/d of total fibre from the enteral formula. During each phase of the study, children gained weight compared with baseline (Table 4). However, no significant changes in height or body composition were observed (Table 4). Neither stool frequency nor consistency differed significantly between the two formulas, but an increase in stool consistency was observed during the TEN period. Furthermore, no significant changes in the frequency or severity of GI symptoms (belching, nausea, vomiting, pain, flatulence and bloating) were recorded between the two diets. A tendency towards a carry-over effect for both the frequency (P = 0·061) and severity (P = 0·056) of nausea was observed. Twelve of the twenty-seven subjects were using polyethylene glycol laxatives (Forlax®) upon inclusion (ten out of twenty upon completion) and administration remained chronic and stable throughout the study. Overall drug use remained high in the present study population (Table 5).

Table 3 Baseline general characteristics of patients in each group

(Mean values and standard deviations for parametric variables or median (range) for non-parametric variables, frequency)

M, male; F, female.

*  Group A: Tentrini®, then Tentrini® Multi Fibre; Group B: Tentrini® Multi Fibre, then Tentrini®.

Table 4 Changes in growth and body composition of children after 3 months

(Mean values with their standard errors)

TEN, tentrini; TMF, tentrini MF; MF, multifibre; FFM, fat-free mass; FM, fat mass.

* Mean values were significantly different (P < 0·05).

 Determined using skinfold thickness measurements at four sites – triceps, biceps, supra-iliac and subscapular.

Table 5 Percentage of children on medication throughout the study

Mean values were significantly different (higher) in centre V v. centre L: *P < 0·001, **P < 0·05.

 Trend P = 0·057.

A carry-over effect was observed for clostridia and vitamin C, respectively. Therefore, we excluded these parameters from further analysis.

A significant increase in the proportion of bifidobacteria (+16·6 %) was observed in the faeces of children in the fibre (TMF) period than in the faeces of those in the fibre-free (TEN) period ( − 11·3 %) (Table 6). No significant differences were observed in the faecal counts of lactobacilli, E. coli or specific subgroups of clostridia between the two diet phases (Table 6). Faecal pH was reduced ( − 0·3) when subjects were fed TMF (P < 0·001; Table 6). However, this was not accompanied by any significant changes in SCFA levels, possibly due to the very low number of stool samples available for this analysis (Table 6).

Table 6 Changes in faecal microbiota and SCFA of children after 3 months

(Mean values with their standard errors)

TEN, tentrini; TMF, tentrini MF; MF, multifibre.

*** Mean values were significantly different (P < 0·001).

 Significant period effect (P < 0·05).

 Significant difference between both endpoints.

§  One-tailed test.

 Significant carry-over effect.

The majority of blood parameters did not change across time or treatment (Table 7). Glutathione peroxidase (P = 0·058) and superoxide dismutase (P < 0·05) levels showed trends of increasing after 3 months on TMF, though no significant differences across diets were observed. However, there was a significantly increased Fe status in patients on TEN, as evidenced by their raised ferritin levels (P < 0·01), which was not observed in the children during the TMF period. However, ferritin levels remained within safe and normal ranges (20–300 ng/ml) during both intervention phases.

Table 7 Changes in blood parameters of children after 3 months

(Mean values with their standard errors)

TEN, tentrini; TMF, Tentrini MF; MF, multifibre; MCV, mean corpuscular volume; GPx, glutathione peroxidase; SOD, superoxide dismutase.

*  Mean values were significantly different (P < 0·05).

 Significant period effect P < 0·05.

 Significant carry-over effect.

§  Significant difference between both treatment endpoints.

Discussion

To the best of our knowledge, the present study is the first to evaluate the effect of fibre-supplemented formula on gut microbiota in enterally fed children. There are only a limited number of studies available assessing the benefits of fibre supplementation in paediatric nutritional support, and most of them are reported only in abstract form(Reference Tolia, Ventimiglia and Kuhns12Reference Elia, Engfer and Green15). The present study clearly shows a strong effect of multifibre on bifidobacteria, with increased counts (+16·6 %) in children when fed TMF than when fed TEN.

The multifibre mixture (MF6™) used in the present study contains soya polysaccharides, fructo-oligosaccharides, cellulose, inulin, gum arabic and resistant starch, and has been designed to allow fibres to be fermented along the large intestine(Reference Cherbut32Reference Roberfroid35) and to yield SCFA by-products that fuel colonocytes and exert a trophic effect on enteric bacteria(Reference Schneider, Girard-Pipau and Anty36). However, while stool pH significantly decreased during the multifibre period, no changes in faecal SCFA levels were observed in the present study. A previous study using the same fibre mixture, but at a higher level (1·5 g/100 ml feed), has shown an increase in butyrate and acetate after feeding adult patients the multifibre-supplemented feed for 14 d(Reference Schneider, Girard-Pipau and Anty36). However, this did not translate into any changes in the counts of dominant gut bacteria, as observed in the present study. Therefore, this led us to believe that the relationship between the stimulation of SCFA production and proliferation of gut microbiota is not a simple linear one(Reference Vogt and Wolever37). Another reason for the lack of effect on stool SCFA levels could be the very small sample size (n 5) available for SCFA analysis. Therefore, we would suggest a sample consisting of minimum ten patients as described in the study done by Schneider et al.(Reference Schneider, Girard-Pipau and Anty36). Furthermore, stool SCFA levels do not necessarily reflect the grade of SCFA production in the gut(Reference Vogt and Wolever37). The fibre intake of the children may have been too low (8·4 (sd 2·2) g/d) from the fibre-supplemented formula) and/or the period of fibre supplementation may have been too short for an effect on stool SCFA levels. Finally, significant levels of lactate are only found in baby faeces, therefore it was not included in the analysis plan. Unfortunately, we did not have suitable samples left to measure lactate also.

In the present study, we targeted representative bacterial groups as biomarkers to study the dynamics of the faecal microbiota of the children, with bifidobacteria and lactobacilli being potentially health-promoting bacteria, and E. coli and a specific group of clostridia also containing potentially pathogenic strains. Members of the Clostridium histolyticum/Clostridium lituseburense group comprise pathogenic Clostridium difficile and Clostridium perfringens species(Reference Franks, Harmsen and Raangs24) that are generally known to be harmful toxin-producing species causing diarrhoea and food poisoning. Our findings of an increase in the proportion of stool bifidobacteria and a reduction in faecal pH during the TMF (fibre) period are assumed to be of benefit to the enterally fed children. A bifidobacteria-dominant microbiota may prevent pathogen invasion(Reference Gibson, McCartney and Rastall38) and help activate the immune system(Reference Salminen, Bouley and Boutron-Ruault39), as well as synthesise vitamins and digestive enzymes(Reference Gibson and Roberfroid33), thus stimulating the development of a healthier gut. Furthermore, a lowered gut pH favours the selective proliferation of lactic acid bacteria over pathogens(Reference Lievin-le Moal and Servin40). Such benefits are of direct interest in the paediatric population who are often fed enterally from a very early age, and this is continued for a prolonged period of time, sometimes even for a lifetime(Reference Daveluy, Guimber and Mention1). Despite heavy medication in this study population, TMF was effective at promoting the proliferation of bifidobacteria to yield a healthier gut microbiota. Clinical benefits related to these findings remain to be investigated in this population.

Use of a large amount of a single (insoluble or soluble) fibre source in EN has been reported to cause digestive side effects, including bloating, diarrhoea, flatulence, vomiting and abdominal pain(Reference Sobotka, Bratova and Slemrova41, Reference Cummings and Macfarlane42). In the present study, the use of the MF6™ mixture was well tolerated by children, and did not cause any GI symptoms. This finding is fully in line with results from previous studies in children and adults using formulas supplemented with the same multifibre mixture, where the fibre-containing feeds were reported to be well tolerated(Reference Trier, Wells and Thomas13Reference Elia, Engfer and Green15, Reference Schneider, Girard-Pipau and Anty36, Reference Silk, Walters and Duncan43).

One of the expected benefits of using fibre was a reduction in constipation. Previous clinical studies using the multi-fibre blend (MF6™) have reported improvements in stool consistency in both paediatric and adult enterally fed patients(Reference Trier, Wells and Thomas13, Reference Hofman, van Drunen and Brinkman14, Reference Silk, Walters and Duncan43, Reference Vandewoude, Paridaens and Suy44). In a study in paediatric burn patients, a tube feed enriched with the same fibre mixture was well tolerated and it reduced the use of laxatives compared with a fibre-free tube feed(Reference Hofman, van Drunen and Brinkman14). Furthermore, a 2-week, cross-over study in sixteen children, ten of whom had cerebral palsy, in which a multifibre-supplemented paediatric tube feed was compared with a fibre-free feed, showed a significant reduction in the number of days of constipation during the fibre period(Reference Trier, Wells and Thomas13). Vandewoude et al.(Reference Vandewoude, Paridaens and Suy44) reported a reduction in the incidence of hard faeces and a change towards more soft pasty faeces following multifibre supplementation in enterally fed elderly patients. In addition, the use of an adult tube feed enriched with the multifibre blend (MF6) normalised whole gut transit time and re-established colonic activity after nasogastric bolus in adult patients(Reference Silk, Walters and Duncan43). A recent randomised, double-blind study in adults receiving fructo-oligosaccharides and fibre-supplemented enteral formula showed a positive correlation between gastrointestinal quality of life index score and the number of faecal bifidobacteria, suggesting that a change in intestinal microbiota could induce an increased quality of life in these patients(Reference Wierdsma, Van Bodegraven and Uitdehaag45).

However, in the present study, all patients who were constipated and received laxatives at study entry remained constipated during follow-up, independent of the type of formula they received. This could be partly due to inadequate total fibre intakes. Indeed, children were consuming less than 50 % of their recommended intake of fibre, even when combining fibre intake from the enteral feed (8·3 g) and from their oral diet (2·4 g). A recent study showed an improvement in constipation in children aged 8–14 years when their dietary fibre intakes were at least 14·5 g/d(Reference Chao, Lai and Kong46). Furthermore, it was recently reported that giving children a high amount of a dietary fibre mixture (20 g/d in children of 15–20 kg and 30 g/d in those >20 kg) was effective in the treatment of childhood constipation(Reference Chao, Lai and Kong46).

In addition to this, the subgroup of neurologically impaired children often had a relatively low intake of enteral formula due to fluid restrictions and/or low energy requirements. Furthermore, these children often suffer from constipation(Reference Sullivan, Lambert and Rose10), and therefore, may have higher requirements of fibre than healthy children(Reference Chao, Lai and Kong46).

Finally, the observation that stool consistency increased during the TEN period, but remained constant during the TMF period, could suggest that the multifibre mixture (MF6™) used in the present study may have a stabilising effect on stool consistency, but this should be investigated further in a larger trial with higher doses of fibre.

During both formula phases of the study, the children gained weight. This is of major relevance in this patient group, as malnutrition in these children can result in serious sequelae affecting organ development and maturation, immune response, GI function, muscle strength, motor function and behaviour(47, Reference Sullivan, Juszczak and Bachlet48). Other studies have reported similar effects on weight gain of gastrostomy tube feeding in children with neurological disabilities(Reference Sullivan, Juszczak and Bachlet48Reference Kong and Wong50). Improvements in linear growth have also been reported, but much less commonly(Reference Rempel, Colwell and Nelson51). Remarkably, in a recent study done by Sullivan et al.(Reference Sullivan, Alder and Bachlet52), a relatively low energy expenditure and high body-fat content were reported in gastrostomy-fed children with severe cerebral palsy, highlighting the potential risk of overfeeding in this patient population. In the present study, no significant changes in height, FM or FFM were observed.

A few questions can be raised regarding the use of BIA in this population with muscle spasticity and abnormal skin texture. Several studies have pointed out the lack of validity of BIA in children with cerebral palsy, indicating a good correlation with FFM, but no reliability for FM determination(Reference Liu, Roberts and Moyer-Mileur53). Attempts should be made to improve the techniques for measuring body composition in this group, as FFM appears to have an impact on motor function and therefore on the quality of life of children with cerebral palsy(Reference Campanozzi, Capano and Miele54, Reference Krigger55).

Very few data are available on micronutrient status in children receiving fibre-supplemented feeds. Daly et al.(Reference Daly, Johnson and MacDonald56) found no differences in plasma Zn, Cu and Se status between children receiving a multifibre-supplemented sip feed for 12 weeks and those receiving a fibre-free feed during this period. Tolia et al.(Reference Tolia, Ventimiglia and Kuhns12) observed no negative effect on micronutrient status with intakes of 8 to 10 soya fibre\d.

In the present study, most of the biological parameters remained unchanged. Nevertheless, plasma ferritin levels showed a significant diet effect. After the 3-month intervention period on fibre-free enteral feeding, plasma ferritin levels increased, whereas no change in the levels was observed during the period on the fibre-supplemented feeds. As plasma ferritin levels remained within normal physiological ranges during both phases of the study, we cannot conclude that a formula enriched with fibre has any impact on the Fe bioavailability of patients.

The data on plasma vitamin C status of the children were inconsistent due to oxidative loss of the vitamin during sample transport. Lastly, the observed increase in glutathione peroxidase and superoxide dismutase levels after 3 months on the fibre-enriched feed could indicate an improved antioxidant capacity, possibly relating to the potential effects of fibre on the gut microbiota. Large, long-term studies with higher levels of fibre are required to assess the effect of fibre-enriched formulas on micronutrient status of enterally fed children.

One of the major limitations of the present study was the small sample size. In addition, the pathology of the children included was very heterogeneous. This made the analysis and interpretation of the present study results quite difficult. Another limitation is the under-representation of the female sex in this study population. Although we are unaware of sex differences in the effects of fibre supplementation of enteral feeds on gut microbiota and bowel actions, this may merit further investigation.

Compliance was not assessed in the present study, but as the children had been already fed via gastrostomy before the study, there is no reason to doubt their compliance. Furthermore, weight gain was achieved during the study period, which is an indication of adherence to the feed prescription. Lastly, a carry-over effect was observed for several variables (clostridia, vitamin C and a trend for nausea and stool frequency). This might indicate the need for a longer washout period in subsequent cross-over nutritional intervention studies in enterally fed children.

Conclusion

In conclusion, the present study demonstrates that the use of a multifibre-supplemented paediatric tube feed in long-term enterally fed children is beneficial, as it is well tolerated, promotes the growth of bifidobacteria and reduces gut pH, suggesting an improved gut health.

Further studies are needed to establish the fibre requirements of long-term enterally fed children with neurological disabilities as well as to assess the effect of long-term fibre supplementation on micronutrient status.

Acknowledgements

We thank the children and their parents who took part in the present study. We are grateful to G. Descamp and B. Seignez for their invaluable help in performing the logistic of shipment of nutritional products in the present study. Data quality assurance and collection, logistics of blood samples and technical assistance were assumed by C. Marichez from the Clinical Investigation Center of Lille (CIC-9301-CH&U-Inserm). Stool checking and storage were assumed by the BRC (Biological Ressource Centre) of CIC-9301-CH&U-Inserm. The sponsor of the present study was Nutricia Advanced Medical Nutrition, Danone Research, Centre for Specialised Nutrition (The Netherlands). F. G. is a member of the Nutricia International Paediatric Advisory Board. K. B. A., A. G., J. S. and J. K. are employees of Danone Research. D. G., F. G., L. B. and A. G. contributed to the design of the study. L. B., S. N. and B. B. were responsible for data collection and analysis. J. K. performed stool analysis. D. G., F. G. and A. G. prepared the final manuscript.

References

1Daveluy, W, Guimber, D, Mention, K, et al. (2005) Home enteral nutrition in children: an 11-year experience with 416 patients. Clin Nutr 24, 4854.CrossRefGoogle ScholarPubMed
2Lunn, J & Buttriss, JL (2007) Carbohydrates and dietary fibre. Nutr Bull 32, 2164.CrossRefGoogle Scholar
3Alexy, U, Kersting, M & Sichert-Hellert, W (2006) Evaluation of dietary fibre intake from infancy to adolescence against various references – results of the DONALD Study. Eur J Clin Nutr 60, 909914.CrossRefGoogle ScholarPubMed
4Williams, CL (2006) Dietary fiber in childhood. J Pediatr 149, 121130.CrossRefGoogle Scholar
5Marlett, JA, McBurney, MI & Slavin, J (2002) Position of the American Dietetic Association: health implications of dietary fiber. J Am Diet Assoc 102, 9931000.CrossRefGoogle ScholarPubMed
6Edwards, CA & Parrett, AM (2003) Dietary fibre in infancy and childhood. Proc Nutr Soc 62, 1723.CrossRefGoogle ScholarPubMed
7Marlett, JA, McBurney, MI & Slavin, JL (2002) Position of the American Dietetic Association: health implications of dietary fiber. J Am Diet Assoc 102, 9931000.CrossRefGoogle ScholarPubMed
8López-Herce, J, Santiago, MJ, Sánchez, C, et al. (2008) Risk factors for gastrointestinal complications in critically ill children with transpyloric enteral nutrition. Eur J Clin Nutr 62, 395400.CrossRefGoogle ScholarPubMed
9Sánchez, C, López-Herce, J, Carrillo, A, et al. (2006) Transpyloric enteral feeding in the postoperative of cardiac surgery in children. J Pediatr Surg 41, 10961102.CrossRefGoogle ScholarPubMed
10Sullivan, PB, Lambert, B, Rose, M, et al. (2000) Prevalence and severity of feeding and nutritional problems in children with neurological impairment: Oxford Feeding Study. Dev Med Child Neurol 42, 674680.CrossRefGoogle ScholarPubMed
11Del Giudice, E, Staiano, A, Capano, G, et al. (1999) Gastrointestinal manifestations in children with cerebral palsy. Brain Dev 21, 307311.CrossRefGoogle ScholarPubMed
12Tolia, V, Ventimiglia, J & Kuhns, L (1997) Gastrointestinal tolerance of a pediatric fiber formula in developmentally disabled children. J Am Coll Nutr 16, 224228.CrossRefGoogle ScholarPubMed
13Trier, E, Wells, JCK & Thomas, AG (1999) Effect of a multifibre supplemented paediatric enteral feed on gastrointestinal function. J Pediatr Gastroenterol Nutr 28, 595(abstract).Google Scholar
14Hofman, Z, van Drunen, J, Brinkman, J, et al. (2001) Tolerance and efficacy of a multi-fibre enriched tube-feed in paediatric burn patients. Clin Nutr 20, 6364.Google Scholar
15Elia, M, Engfer, MB, Green, CJ, et al. (2007) Systematic review and meta-analysis: the clinical and physiological effects of fibre-containing enteral formulae. Aliment Pharmacol Ther 27, 0145.Google ScholarPubMed
16Durnin, J & Womersley, J (1974) Body fat assessed from total body density and its estimation from skinfold thickness: measurements on 481 men and women aged from 16 to 72 years. Br J Nutr 32, 7797.CrossRefGoogle ScholarPubMed
17Brook, C (1971) Determination of body composition of children from skinfold measurements. Arch Dis Child 46, 182184.CrossRefGoogle ScholarPubMed
18Durnin, J & Rahaman, M (1967) The assessment of the amount of fat in the human body from measurements of skinfold thickness. Br J Nutr 21, 681689.CrossRefGoogle ScholarPubMed
19Siri, W (1993) Body composition from fluid spaces and density: analysis of methods. 1961. Nutrition 9, 480491.Google ScholarPubMed
20Schaefer, F, Georgi, M, Zieger, A, et al. (1994) Usefulness of bioelectric impedance and skinfold measurement in predicting fat-free mass derived from total body potassium in children. Pediatr Res 35, 617624.CrossRefGoogle ScholarPubMed
21Langendijk, PS, Schut, F, Gijsbert, J, et al. (1995) Quantitative fluorescence in situ hybridization of Bifidobacterium spp. with genus-specific 16S rRNA-targeted probes and its application in fecal samples. Appl Environ Microbiol 61, 30693075.CrossRefGoogle ScholarPubMed
22Harmsen, HJM, Gibson, GR, Elfferich, P, et al. (2000) Comparison of viable cell counts and fluorescence in situ hybridization using specific rRNA-based probes for the quantification of human fecal bacteria. FEMS Microbiol Lett 183, 125129.CrossRefGoogle ScholarPubMed
23Poulsen, LK, Lan, F, Kristensen, CS, et al. (1994) Spatial distribution of Escherichia coli in the mouse large intestine inferred from rRNA in situ hybridization. Infect Immun 62, 51915194.CrossRefGoogle ScholarPubMed
24Franks, AH, Harmsen, HJM, Raangs, GC, et al. (1998) Variations of bacterial populations in human feces measured by fluorecent in situ hybridization with group-specific 16S rRNA-targeted oligonucleotide probes. Appl Environ Microbiol 64, 33363345.CrossRefGoogle Scholar
25Thiel, R & Blaut, M (2005) An improved method for the automated enumeration of fluorescently labelled bacteria in human faeces. J Microbiol Methods 61, 369379.CrossRefGoogle ScholarPubMed
26Knol, J, Scholtens, P, Kafka, C, et al. (2005) Colon microflora in infants fed formula with galacto- and fructo-oligosaccharides: more like breast-fed infants. J Pediatr Gastroenterol Nutr 40, 3642.Google ScholarPubMed
27MacCrehan, A & Schönberger, E (1987) Determination of retinol, α-tocopherol, and β-carotene in serum by liquid chromatography with absorbance and electrochemical detection. Clin Chem 33, 15851592.CrossRefGoogle ScholarPubMed
28Lee, W, Roberts, SM & Labbe, RF (1997) Ascorbic acid determination with an automated enzymatic procedure. Clin Chem 43, 154157.CrossRefGoogle ScholarPubMed
29Paglia, D & Valentine, W (1967) Studies on the quantitative and qualitative characterization of erythrocyte glutathione peroxydase. J Lab Clin Med 70, 158169.Google Scholar
30McCord, D & Fridovich, C (1969) Superoxyde dismutase activity in red blood cells. J Biol Chem 24, 60496055.CrossRefGoogle Scholar
31Altman, D (1991) Section 15.4.10. In Practical Statistics for Medical Research, 1st ed. London: Chapman & Hall.Google Scholar
32Cherbut, C (2002) Inulin and oligofructose in the dietary fibre concept. Br J Nutr 87, S159S162.CrossRefGoogle ScholarPubMed
33Gibson, GR & Roberfroid, MB (1995) Dietary modulation of the human colonic microbiota: introducing the concept of prebiotics. J Nutr 125, 14011412.CrossRefGoogle ScholarPubMed
34Roberfroid, M (2005) Introducing inulin-type fructans. Br J Nutr 93, S13S25.CrossRefGoogle ScholarPubMed
35Roberfroid, MB (1999) Concepts in functional foods: the case of inulin and oligofructose. J Nutr 129, S1398S1401.CrossRefGoogle ScholarPubMed
36Schneider, S, Girard-Pipau, F, Anty, R, et al. (2006) Effects of total enteral nutrition supplemented with a multi-fibre mix on faecal short-chain fatty acids and microbiota. Clin Nutr 25, 8290.CrossRefGoogle ScholarPubMed
37Vogt, JA & Wolever, TM (2003) Fecal acetate is inversely related to acetate absorption from the human rectum and distal colon. J Nutr 133, 31453148.CrossRefGoogle ScholarPubMed
38Gibson, GR, McCartney, AL & Rastall, RA (2005) Prebiotics and resistance to gastrointestinal infections. Br J Nutr 93, Suppl. 1, S31S34.CrossRefGoogle ScholarPubMed
39Salminen, S, Bouley, C, Boutron-Ruault, MC, et al. (1998) Functional food science and gastro-intestinal physiology and function. Br J Nutr 80, Suppl. 1, S147S171.CrossRefGoogle Scholar
40Lievin-le Moal, V & Servin, AL (2006) The front line of enteric host defense against unwelcome intrusion of harmful microorganisms: mucins, antimicrobial peptides, and microbiota. Clin Microbiol Rev 19, 315337.CrossRefGoogle ScholarPubMed
41Sobotka, L, Bratova, M, Slemrova, M, et al. (1997) Inulin as the soluble fiber in liquid enteral nutrition. Nutrition 13, 2125.CrossRefGoogle ScholarPubMed
42Cummings, J & Macfarlane, G (1991) The control and consequences of bacterial fermentation in the human colon. J Appl Bacteriol 70, 443459.CrossRefGoogle ScholarPubMed
43Silk, D, Walters, E, Duncan, H, et al. (2001) The effect of a polymeric enteral formula supplemented with a mixture of six fibres on normal human bowel function and colonic motility. Clin Nutr 20, 4958.CrossRefGoogle ScholarPubMed
44Vandewoude, MF, Paridaens, KM, Suy, RA, et al. (2005) Fibre-supplemented tube feeding in the hospitalised elderly. Age Ageing 34, 120124.CrossRefGoogle ScholarPubMed
45Wierdsma, NJ, Van Bodegraven, AA, Uitdehaag, BM, et al. (2009) Fructo-oligosaccharides and fibre in enteral nutrition has a beneficial influence on microbiota and gastrointestinal quality of life. Scand J Gastroenterol 6, 19.Google Scholar
46Chao, HC, Lai, MW, Kong, MS, et al. (2008) Cutoff volume of fibre to ameliorate constipation in chidren. J Pediatr 153, 4549.CrossRefGoogle Scholar
47Nutrition Committee, Canadian Paediatric Society (1994) Undernutrition in children with a neurodevelopmental disability. CMAJ 151, 753759.Google Scholar
48Sullivan, PB, Juszczak, E, Bachlet, AM, et al. (2005) Gastrostomy tube feeding in children with cerebral palsy: a prospective, longitudinal study. Dev Med Child Neurol 47, 7785.CrossRefGoogle ScholarPubMed
49Brant, CQ, Stanich, P, Ferrari, AP Jr, et al. (1999) Improvement of children's nutritional status after enteral feeding by PEG: an interim report. Gastrointest Endosc 50, 183188.CrossRefGoogle ScholarPubMed
50Kong, CK & Wong, HS (2005) Weight-for-height values and limb anthropometric composition of tube-fed children with quadriplegic cerebral palsy. Pediatrics 116, 839845.CrossRefGoogle ScholarPubMed
51Rempel, GR, Colwell, SO & Nelson, RP (1988) Growth in children with cerebral palsy fed via gastrostomy. Pediatrics 82, 857862.CrossRefGoogle ScholarPubMed
52Sullivan, PB, Alder, N, Bachlet, AM, et al. (2006) Gastrostomy feeding in cerebral palsy: too much of a good thing? Dev Med Child Neurol 48, 877882.CrossRefGoogle ScholarPubMed
53Liu, L, Roberts, R, Moyer-Mileur, L, et al. (2005) Determination of body composition in children with cerebral palsy: bioelectrical impedance analysis and anthropometry vs dual-energy X-ray absorptiometry. J Am Diet Assoc 105, 794797.CrossRefGoogle ScholarPubMed
54Campanozzi, A, Capano, G, Miele, E, et al. (2007) Impact of malnutrition on gastrointestinal disorders and gross motor abilities in children with cerebral palsy. Brain Dev 29, 2529.CrossRefGoogle ScholarPubMed
55Krigger, K (2006) Cerebral palsy: an overview. Am Fam Physician 73, 91100.Google ScholarPubMed
56Daly, A, Johnson, T & MacDonald, A (2004) Is fibre supplementation in paediatric sip feeds beneficial? J Hum Nutr Diet 17, 365370.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Nutritional composition of the paediatric study formulas per 100 ml

Figure 1

Table 2 List of the 16S rRNA-targeted oligonucleotides used in the present study

Figure 2

Table 3 Baseline general characteristics of patients in each group(Mean values and standard deviations for parametric variables or median (range) for non-parametric variables, frequency)

Figure 3

Table 4 Changes in growth and body composition of children after 3 months(Mean values with their standard errors)

Figure 4

Table 5 Percentage of children on medication throughout the study

Figure 5

Table 6 Changes in faecal microbiota and SCFA of children after 3 months(Mean values with their standard errors)

Figure 6

Table 7 Changes in blood parameters of children after 3 months(Mean values with their standard errors)