Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-28T21:08:15.508Z Has data issue: false hasContentIssue false

Prebiotics in inflammatory bowel diseases

Published online by Cambridge University Press:  01 October 2007

Francisco Guarner*
Affiliation:
Digestive System Research UnitCiberehd University Hospital Vall d'HebronPasseig Vall d'Hebron, 119-12908035Barcelona, Spain
*
*Corresponding author: Francisco Guarner, fax +34 934894456, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

In genetically susceptible individuals, an altered mucosal immune response against some commensal bacteria of the gut ecosystem appears to be the principal mechanism leading to intestinal lesions in inflammatory bowel disease (IBD). The information currently available does not provide an exact explanation about the origin of this important dysfunction of the interaction between host and commensal bacteria, but an altered microbial composition has been detected in the gut ecosystem of patients with Crohn's disease or ulcerative colitis. Prebiotics are food ingredients not digested nor absorbed in the upper intestinal tract that are fermented by intestinal bacteria in a selective way promoting changes in the gut ecosystem. Experimental and human studies have shown that inulin and oligofructose stimulate saccharolysis in the colonic lumen and favour the growth of indigenous lactobacilli and bifidobacteria. These effects are associated with reduced mucosal inflammation in animal models of IBD. Strong experimental evidence supports the hypothesis that inulin and oligofructose can offer an opportunity to prevent or mitigate intestinal inflammatory lesions in human Crohn's disease, ulcerative colitis, and pouchitis. Encouraging results have been obtained in preliminary clinical trials.

Type
Full Papers
Copyright
Copyright © The Author 2007

The term ‘inflammatory bowel disease’ (IBD) refers mainly to three separate clinical entities: Crohn's disease, ulcerative colitis and pouchitis. These diseases are characterized by persistent mucosal inflammation at different levels of the gastrointestinal tract. Typically, IBDs exhibit undulating activity with bouts of uncontrolled, chronic mucosal inflammation, followed by remodelling processes that occur during periods of remission. Incidence of such diseases has been growing steadily during the past 5 decades in Western Europe, and is now expanding dramatically in Asian and Eastern European countriesReference Loftus1. IBDs are becoming an important burden also in young populationsReference Sawczenko, Sandhu, Logan, Jenkins, Taylor, Mian and Lynn2.

The precise aetiologies of these chronic inflammatory conditions remain to be elucidated, but the most important pathophysiological mechanisms that lead to the mucosal inflammatory lesions are being unveiled. These mechanisms result from complex interaction of environmental, genetic and immunoregulatory factors. Abnormal communication between gut microbial communities and the mucosal immune system has been suggested as the core defect leading to IBD in genetically susceptible individualsReference Strober, Fuss and Mannon3. Within the gastrointestinal tract, the inflammatory capacity of commensal bacteria is varied. Some resident bacteria are proinflammatory, whereas others attenuate inflammatory responsesReference García-Lafuente, Antolín, Guarner, Crespo, Salas, Forcada, Laguarda, Gavaldá, Baena, Vilaseca and Malagelada4Reference O'Hara, O'Regan, Fanning, O'Mahony, Macsharry, Lyons, Bienenstock, O'Mahony and Shanahan6. Prebiotics such as inulin and oligofructose can improve the microbial balance in the human gut microbiota by increasing the number and activity of bacteria associated with health benefitsReference Roberfroid7. This article reviews experimental and clinical evidence supporting the use of prebiotics for the prevention and control of IBD.

The gut microbiota

The term “microflora” or “microbiota” refers to the community of living micro-organisms assembled in a particular ecological niche of a host individual. The human gut is the natural habitat for a large, diverse and dynamic population of micro-organisms which over millennia have adapted to live on the mucosal surfaces or in the lumenReference Guarner and Malagelada8. The number of resident bacteria increases along the small bowel, from approximately 10Reference García-Lafuente, Antolín, Guarner, Crespo, Salas, Forcada, Laguarda, Gavaldá, Baena, Vilaseca and Malagelada4 in the jejunum to 10Reference Roberfroid7 colony-forming units per gram of luminal content in the distal ileum. The large intestine is the most heavily populated region of intestine, where several hundred grams of bacteria are harboured at densities around 10Reference Guarner, Bourdet-Sicard, Brandtzaeg, Gill, McGuirk, van Eden, Versalovic, Weinstock and Rook12 colony forming units per gram of luminal content.

Our current knowledge about the microbial composition of the intestinal ecosystem in health and disease is still very limited. Studies using classical techniques of microbiological culture can only recover a minor fraction of faecal bacteria. Over 50 % of bacteria cells that are observed by microscopic examination of faecal specimens cannot be grown in cultureReference Suau, Bonnet, Sutren, Godon, Gibson, Collins and Dore9. Molecular biological techniques based on the sequence diversity of the bacterial genome are being used to characterize non-cultivable bacteriaReference Eckburg, Bik, Bernstein, Purdom, Dethlefsen, Sargent, Gill, Nelson and Relman10. Molecular studies on the faecal microbiota have highlighted that only 7 of the 55 known divisions or superkingdoms of the domain ‘bacteria’ are detected in the human gut ecosystem, and of these, 3 bacterial divisions dominate, i.e. Bacteroidetes, Firmicutes and Actinobacteria. However, at species and strain level, microbial diversity between individuals is highly remarkable up to the point that each individual harbours his or her own distinctive pattern of bacterial compositionReference Eckburg, Bik, Bernstein, Purdom, Dethlefsen, Sargent, Gill, Nelson and Relman10.

On the other hand, studies comparing animals bred under germ-free conditions with their conventionally raised counterparts have clearly demonstrated the important impact of resident bacteria on host physiology. The interaction between gut bacteria and their host is a symbiotic relationship mutually beneficial for both partners. The host provides a nutrient-rich habitat and the bacteria confer important benefits to the hostReference Guarner and Malagelada8. Functions of the microbiota include nutrition (fermentation of nondigestible substrates that results in production of short chain fatty acids, absorption of ions, production of aminoacids and vitamins), protection (the barrier effect that prevents invasion by alien microbes), and trophic effects on the intestinal epithelium and the immune system (development and homeostasis of local and systemic immunity).

Animals bred in a germ-free environment show low densities of lymphoid cells in the gut mucosa and low concentrations of serum immunoglobulins. Exposure to commensal microbes rapidly expands the number of mucosal lymphocytes and increases the size of germinal centres in lymphoid follicles. Immunoglobulin producing cells appear in the lamina propria, and there is a significant increase in serum immunoglobulin concentrationsReference Yamanaka, Helgeland, Farstad, Fukushima, Midtvedt and Brandtzaeg11. Most interestingly, recent findings suggest that some commensals play a major role in the induction of regulatory T cells in gut lymphoid folliclesReference Guarner, Bourdet-Sicard, Brandtzaeg, Gill, McGuirk, van Eden, Versalovic, Weinstock and Rook12. Regulatory pathways mediated by regulatory T cells are essential homeostatic mechanisms by which the host can tolerate the massive burden of innocuous antigens within the gut or on other body surfaces without responding through inflammation.

Bacteria and inflammatory bowel disease

The mechanisms of regulation and tolerance of bacterial antigens in the gut microbiota seem to be altered in subjects with IBD. The normal mucosal defence is based mainly on the production of IgA antibodies that are secreted into the gut lumen and neutralize microbes in the lumen, thus avoiding mucosal inflammationReference Cobrin and Abreu13, Reference Brandtzaeg, Carlsen and Halstensen14. In IBD, however, mucosal production of IgG antibodies against intestinal bacteria is highly increased, and mucosal defence relies on both IgG mediated responses within the tissue and hyper-activated lymphocytes in the lamina propria reacting against bacterial antigensReference Cobrin and Abreu13Reference Macpherson, Khoo, Forgacs, Philpott-Howard and Bjarnason15. These events result in inflammation and tissue injury. The altered immune response is not specifically targetted towards a single group of potential pathogens, but involves a large and undefined number of commensal species belonging to the common enteric microbiota. A microbial imbalance in the gut ecosystem could explain the abnormal reactivity of the mucosal immune system against enteric bacteria.

Several studies have shown that the composition of the faecal microbiota differs between subjects with IBD and healthy controlsReference Guarner16. Molecular studies show that a substantial proportion of faecal bacteria (up 30 to 40 % of dominant species) in patients with active Crohn's disease or ulcerative colitis belong to phylogenetic groups that are unusual in healthy subjectsReference Sokol, Seksik, Rigottier-Gois, Lay, Lepage, Podglajen, Marteau and Dore17. These remarkable changes could be secondary to disease activity but they are not observed in patients with infectious diarrhoea. On the other hand, studies have shown reduced diversity of bacteria species in both faecal and mucosa-associated communities in patients with IBDReference Manichanh, Rigottier-Gois, Bonnaud, Gloux, Pelletier, Frangeul, Nalin, Jarrin, Chardon, Marteau, Roca and Dore18, Reference Ott, Musfeldt, Wenderoth, Hampe, Brant, Folsch, Timmis and Schreiber19. Manichanh and coworkersReference Manichanh, Rigottier-Gois, Bonnaud, Gloux, Pelletier, Frangeul, Nalin, Jarrin, Chardon, Marteau, Roca and Dore18 employed a metagenomic approach for exhaustive investigation of bacterial diversity in Crohn's disease and found a striking reduction of Firmicutes in patients in remission compared with healthy controls (Fig. 1).

Fig. 1 The faecal microbiota of patients with Crohn's disease contains a reduced proportion of Firmicutes. The graph shows data from Manichanh and coworkers (ref 18) and represents number of phylotypes per division in 6 healthy persons and 6 patients in clinical remission.

Studies on mucosa-associated bacteria have found high concentrations of adherent bacteria in patients with clinically active ulcerative colitis or Crohn's disease, but not in healthy controlsReference Swidsinski, Ladhoff, Pernthaler, Swidsinski, Loening-Baucke, Ortner, Weber, Hoffmann, Schreiber, Dietel and Lochs20. The concentrations of mucosal adherent bacteria increased progressively with the severity of mucosal inflammation, and the identified bacteria were of faecal origin. The fluorescent in situ hybridization (FISH) technique demonstrated bacterial invasion of the mucosa in most mucosal specimens from ulcerative colitis and Crohn's disease patients, but not in any of the mucosal specimens from controlsReference Kleessen, Kroesen, Buhr and Blaut21. Invading bacteria belonged to a great variety of genera, including Proteobacteria, Enterobacteriaceae, Bacteroides/Prevotella cluster, Clostridium, and sulphate-reducing bacteria. However, mucosal invasion by Bifidobacterium or Lactobacillus species was not detectedReference Kleessen, Kroesen, Buhr and Blaut21. Moreover, Macfarlane and coworkersReference Macfarlane, Furrie, Cummings and Macfarlane22 observed that numbers of adherent non-invading bifidobacteria were lower in rectal biopsies from ulcerative colitis patients than controls.

Prebiotics

A healthy or ‘balanced’ microbiota has been considered to be one that is predominantly saccharolytic and comprises significant numbers of bifidobacteria and lactobacilliReference Cummings, Antoine, Azpiroz, Bourdet-Sicard, Brandtzaeg, Calder, Gibson, Guarner, Isolauri, Pannemans, Shortt, Tuijtelaars and Watzl23. Inulin and oligofructose are prebiotic carbohydrates that resist digestion by intestinal and pancreatic enzymes in the human gastrointestinal tract and are fermented by bacteria living in the intestinal ecosystemReference Gibson, Probert, Van Loo, Rastall and Roberfroid24. When administered in adequate amounts, these prebiotics increase saccharolytic activity within the gut and promote selectively the growth of bifidobacteria. Numerous studies have shown an increase in counts of bifidobacteria in faeces from subjects consuming inulin or oligofructosesReference Roberfroid7, Reference Macfarlane, Macfarlane and Cummings25. Moreover, oral intake of inulin and oligofructoses increases numbers of bifidobacteria and lactobacilli in the mucosa-associated communities of the human colon. Langlands et al.Reference Langlands, Hopkins, Coleman and Cummings26 showed that bifidobacteria and lactobaciilli numbers could be increased more than 10-fold in biopsy mucosal specimens of the proximal and distal colons in subjects fed 15 g of a prebiotic mixture containing inulin and oligofructose for 2 weeks. Likewise, a study with ulcerative colitis patients receiving a synbiotic preparation with a Bifidobacterium strain and oligofructose-enriched inulin showed that counts of bifidobacteria on the rectal mucosa increased 42-foldReference Furrie, Macfarlane, Kennedy, Cummings, Walsh, O'Neil and Macfarlane27.

Hypothetically, by increasing the number of ‘friendly’ bacteria on the mucosal surface, inulin and oligofructose could improve the barrier function in IBD and prevent mucosal colonization by aerobic enterobacteria able to invade. This hypothesis has been tested in a considerable number of experimental studies using different animal models of IBD.

Experimental models of inflammatory bowel disease

The effect of the prebiotic inulin has been tested in the rat model of colitis induced by the chemical dextran sodium sulphate (DSS)Reference Videla, Vilaseca, Antolín, García-Lafuente, Guarner, Crespo, Casalots, Salas and Malagelada28. Oral administration of DSS over 3 to 5 days induces direct toxicity against colonic epithelial cells that results in dysfunction of the mucosal barrier with increased permeability to large size moleculesReference Lugea, Salas, Casalot, Guarner and Malagelada29. These events are followed by crypt destruction and loss of height of the intestinal villi, with subsequent bacterial invasion and mucosal inflammation. In the rat, daily oral administration of inulin increased counts of indigenous lactobacilli in the caecal lumen and reduced the intracolonic pH. In rats exposed to DSS to induce colitis, treatment with oral inulin reduced significantly tissue myeloperoxidase activity, an index of neutrophil infiltration, and mucosal release of inflammatory mediators. Furthermore, inulin-fed rats showed a reduced extent of damaged mucosa and decreased severity of crypt destruction. Histological damage scores were significantly lower in inulin treated rats than in controls (Fig. 2). Treatment with oral inulin was equally effective whether started prior to or during exposure to DSS.

Fig. 2 Scores of colonic mucosal lesion (solid columns, left ‘y’ axis) and tissue content of myeloperoxidase (MPO, open columns, right ‘y’ axis), a marker of leukocyte infiltration, in rats with colitis induced by DDS. Daily administration of 400 mg inulin by oral gavage significantly reduced lesion scores and myeloperoxidase content in colonic tissue (see reference 28).

The effect of oligofructose and inulin alone or in combination with probiotic bifidobacteria was recently tested in the same DSS modelReference Osman, Adawi, Molin, Ahrne, Berggren and Jeppsson30. The prebiotic alone or in combination with B. infantis strains improved significantly the disease activity indexes and decreased colonic myeloperoxidase activity, as well as expression of inflammatory mediators. Interestingly, bacterial translocation to mesenteric lymph nodes and liver decreased significantly in rats treated by prebiotic, probiotic or the combination of both (synbiotic) as compared to colitis controls. The authors concluded that oligofructose and inulin as well as the Bifidobacterium strains tested prevented bacterial invasion and had an anti-inflammatory effect in this model.

Chronic inflammatory lesions can be induced in the distal colon by a single intracolonic administration of trinitro-benzene sulphonic acid (TNBS) diluted in ethanol (usually 20 to 50 mg TNBS in 30 to 50 % ethanol), using a rubber cannula. The effect of oligofructose has been tested in the TNBS model of colitisReference Cherbut, Michel and Lecannu31. Oral administration of oligofructose significantly reduced intracolonic pH, macroscopic lesion scores, and tissue myeloperoxidase activity in TNBS treated rats. In addition, oligofructose increased the concentration of lactate and butyrate as well as counts of lactic acid bacteria in caecal contents. In subsequent ancillary experiments, these investigators demonstrated that a direct intracaecal infusion of lactic acid bacteria together with short chain fatty acids was necessary to reproduce the anti-inflammatory effects of oligofructose. They concluded that fermentation of the prebiotic by lactic acid bacteria was the principal mechanism mediating the anti-inflammatory effect.

Further experimental work evaluated the anti-inflammatory effects of inulin and oligofructose in the transgenic HLA-B27 rat model of spontaneous colitisReference Hoentjen, Welling, Harmsen, Zhang, Snart, Tannock, Lien, Churchill, Lupicki and Dieleman32. Rats transgenic for the human HLA-B27–beta2-microglobulin gene spontaneously develop immune-mediated colitis of variable severity at 2-4 months of age. The disease is characterized by non-bloody diarrhoea and marked inflammatory infiltration of the caecal and colonic mucosa. Hoentjen and coworkersReference Hoentjen, Welling, Harmsen, Zhang, Snart, Tannock, Lien, Churchill, Lupicki and Dieleman32 tested a mixture of oligofructose and inulin in this model of spontaneous colitis, and observed a significant anti-inflammatory effect in rats fed with the prebiotic mixture. Prebiotic treatment reduced gross morphological scores and histological grading of the lesions. In addition, prebiotic treatment reduced the expression of pro-inflammatory cytokines such as IL-1β, but enhanced the expression of regulatory type cytokines (TGF-β).

The effects of the prebiotic lactulose have also been tested in some animal models of intestinal inflammation. Mice deficient of the IL-10 gene spontaneously develop colitis. In the neonatal period, these knockout mice have a decreased level of Lactobacillus species in the colon and an increase in adherent and translocated bacteriaReference Madsen, Doyle, Jewell, Tavernini and Fedorak33. Oral administration of lactulose was shown to normalize counts of lactobacilli in faeces and prevented the development of colitis. Likewise, protective effects of lactulose have been demonstrated in the DSS and TNBS modelsReference Rumi, Tsubouchi, Okayama, Kato, Mozsik and Takeuchi34, Reference Camuesco, Peran, Comalada, Nieto, Di Stasi, Rodriguez-Cabezas, Concha, Zarzuelo and Galvez35. Taken together, all these experimental data give a strong indication of the anti-inflammatory effects of prebiotics in a wide range of animal models of IBD.

Clinical studies

A randomized, placebo-controlled, double-blind, crossover clinical trial tested the effect of inulin in patients with chronic pouchitisReference Welters, Heineman, Thunnissen, van den Bogaard, Soeters and Baeten36. This clinical condition is characterized by chronic mucosal inflammation of the ileal pouch-anal anastomosis in patients that have had a total colectomy. The ileal pouch is surgically constructed in order to function as a faecal reservoir. The inflammatory disorder impairs the function of the reservoir and results in persistent diarrhoea with mucus and blood. Twenty patients with mild disease activity entered the trial and were randomized to begin with either placebo or inulin (24 g per day) for three weeks, using a double-blinded crossover design with a washout period of four weeks. Compared with placebo, dietary supplementation with inulin significantly reduced endoscopic and histological parameters of inflammation of the mucosa of the ileal reservoir (Table 1). The effect was associated with an increase in faecal butyrate and a decrease in the counts of Bacteroides in faeces.

Table 1 Effect of Dietary Inulin Supplementation on Pouchitis Disease Activity Index (PDAI)

Data are means and standard error of the mean, in brackets, and were published by Welters and coworkers (ref. 36). NS =  not significant.

Furrie et al.Reference Furrie, Macfarlane, Kennedy, Cummings, Walsh, O'Neil and Macfarlane27 reported a randomized, placebo-controlled, double-blind clinical trial in two parallel groups of patients with ulcerative colitis. Eligible patients had mild disease activity and were on stable medication. Eighteen patients were randomized to receive for a period of 1 month either a synbiotic preparation (oligofructose-enriched inulin at 12 g per day, and Bifidobacterium longum at 200 billion colony forming units per day) or placebo (maltodextrin). Synbiotic treatment induced significant reduction of mucosal expression of proinflammatory cytokines (TNF-α, IL-1β) and inducible beta-defensins. Histological examination of biopsies showed marked decrease in inflammatory cell infiltrate and crypt abscesses in patients receiving the synbiotic, together with improved sigmoidoscopy scores and clinical activity indices, but differences were not significant due to the reduced number of patients enrolled.

The effect of oligofructose-enriched inulin in patients with active ulcerative colitis was recently tested in a randomized, placebo-controlled, double-blind pilot trial with two parallel groupsReference Casellas, Borruel, Torrejon, Varela, Antolin, Guarner and Malagelada37. Eligible patients had been previously in remission with mesalazine as maintenance therapy or no drug, and presented to the hospital for relapse of mild-moderate activity. They were treated with mesalazine (3 g/day) and randomly allocated to receive either oligofructose-enriched inulin (12 g/day) or placebo (12 g/day of maltodextrin) for two weeks. The primary endpoint was the anti-inflammatory effect of the prebiotic as assessed by objective, non-invasive markers of intestinal inflammation, i.e. faecal concentration of calprotectin. Calprotectin is a protein found in granulocytes that resists metabolic degradation and can be measured in faeces. Interestingly, at day 7, an early significant reduction of calprotectin was observed in the group receiving oligofructose-enriched inulin but not in the placebo group. At the end of the study period, disease activity scores were significantly reduced in the two groups. Use of this prebiotic may improve response to medical therapy with mesalazine, but this point needs further investigation in a trial with adequate number of patients.

Prebiotics have also been tested in Crohn's disease. In a small open-label trial, 10 patients with active ileo-colonic Crohn's disease were given 15 g of oligofructose per day for 3 weeksReference Lindsay, Whelan, Stagg, Gobin, Al-Hassi, Rayment, Kamm, Knight and Forbes38. All but two patients exhibited a decline in the Harvey Bradshaw index of disease activity after three weeks on oral oligofructose, and the group as a whole showed a significant fall in disease activity as compared to baseline. There was a significant increase in bifidobacteria numbers in faeces but not in rectal biopsies. However, this study did not include a placebo-control group. A controlled study in Crohn's disease patients with appropriate sample size is now being performed by the same group of investigators.

Taken together, experimental and clinical data so far support the hypothesis that prebiotics such as inulin and oligofructose can offer an opportunity to prevent or mitigate intestinal inflammatory lesions in human Crohn's disease, ulcerative colitis, and pouchitis. Controlled clinical trials of appropriated sample size are still needed to confirm this hypothesis.

Conflict of interest statement

Some of the work described in the article was performed in the author's institution, Digestive System Research Unit, which is supported in part by grants from Generalitat de Catalunya (RE: 2001SGR00389) and Instituto de Salud Carlos III (Ciberehd, Spain). The author is member of the Beneo Scientific Committee sponsored by Orafti (Tienen, Belgium), a company that produces prebiotics.

References

1Loftus, EV (2004) Clinical epidemiology of inflammatory bowel disease: incidence, prevalence, and environmental influences. Gastroenterology 126, 15041517.CrossRefGoogle ScholarPubMed
2Sawczenko, A, Sandhu, B, Logan, R, Jenkins, H, Taylor, C, Mian, S & Lynn, R (2001) Prospective survey of childhood inflammatory bowel disease in the British Isles. Lancet 357, 10931094.CrossRefGoogle ScholarPubMed
3Strober, W, Fuss, I & Mannon, P (2007) The fundamental basis of inflammatory bowel disease. J Clin Invest 117, 514521.CrossRefGoogle ScholarPubMed
4García-Lafuente, A, Antolín, M, Guarner, F, Crespo, E, Salas, A, Forcada, P, Laguarda, M, Gavaldá, J, Baena, JA, Vilaseca, J & Malagelada, JR (1997) Incrimination of anaerobic bacteria in the induction of experimental colitis. Am J Physiol 272, G10G15.Google ScholarPubMed
5Borruel, N, Casellas, F, Antolín, M, Carol, M, Llopis, M, Espín, E, Naval, J, Guarner, F & Malagelada, JR (2003) Effects of nonpathogenic bacteria on cytokine secretion by human intestinal mucosa. Am J Gastroenterol 98, 865870.Google ScholarPubMed
6O'Hara, AM, O'Regan, P, Fanning, A, O'Mahony, C, Macsharry, J, Lyons, A, Bienenstock, J, O'Mahony, L & Shanahan, F (2006) Functional modulation of human intestinal epithelial cell responses by Bifidobacterium infantis and Lactobacillus salivarius. Immunology 118, 202215.CrossRefGoogle ScholarPubMed
7Roberfroid, MB (2005) Introducing inulin-type fructans. Br J Nutr 93, Suppl 1, S13S25.Google ScholarPubMed
8Guarner, F & Malagelada, JR (2003) Gut flora in health and disease. Lancet 361, 512519.CrossRefGoogle ScholarPubMed
9Suau, A, Bonnet, R, Sutren, M, Godon, JJ, Gibson, G, Collins, MD & Dore, J (1999) Direct rDNA community analysis reveals a myriad of novel bacterial lineages within the human gut. Appl Environ Microbiol 65, 4.7994.807.CrossRefGoogle Scholar
10Eckburg, PB, Bik, EM, Bernstein, CN, Purdom, E, Dethlefsen, L, Sargent, M, Gill, SR, Nelson, KE & Relman, DA (2005) Diversity of the human intestinal microbial flora. Science 308, 16351638.CrossRefGoogle ScholarPubMed
11Yamanaka, T, Helgeland, L, Farstad, IN, Fukushima, H, Midtvedt, T & Brandtzaeg, P (2003) Microbial colonization drives lymphocyte accumulation and differentiation in the follicle-associated epithelium of Peyer's patches. J Immunol 170, 816822.CrossRefGoogle ScholarPubMed
12Guarner, F, Bourdet-Sicard, R, Brandtzaeg, P, Gill, HS, McGuirk, P, van Eden, W, Versalovic, J, Weinstock, JV & Rook, GA (2006) Mechanisms of Disease: the hygiene hypothesis revisited. Nat Clin Pract Gastroenterol Hepatol 3, 275284.Google ScholarPubMed
13Cobrin, GM & Abreu, MT (2005) Defects in mucosal immunity leading to Crohn's disease. Immunol Rev 206, 277295.CrossRefGoogle ScholarPubMed
14Brandtzaeg, P, Carlsen, HS & Halstensen, TS (2006) The B-cell system in inflammatory bowel disease. Adv Exp Med Biol 579, 149167.CrossRefGoogle ScholarPubMed
15Macpherson, A, Khoo, UY, Forgacs, I, Philpott-Howard, J & Bjarnason, I (1996) Mucosal antibodies in inflammatory bowel disease are directed against intestinal bacteria. Gut 38, 365375.CrossRefGoogle ScholarPubMed
16Guarner, F (2005) The intestinal flora in inflammatory bowel disease: normal or abnormal? Curr Opin Gastroenterol 21, 414418.Google ScholarPubMed
17Sokol, H, Seksik, P, Rigottier-Gois, L, Lay, C, Lepage, P, Podglajen, I, Marteau, P & Dore, J (2006) Specificities of the fecal microbiota in inflammatory bowel disease. Inflamm Bowel Dis 12, 106111.CrossRefGoogle ScholarPubMed
18Manichanh, C, Rigottier-Gois, L, Bonnaud, E, Gloux, K, Pelletier, E, Frangeul, L, Nalin, R, Jarrin, C, Chardon, P, Marteau, P, Roca, J & Dore, J (2006) Reduced diversity of faecal microbiota in Crohn's disease revealed by a metagenomic approach. Gut 55, 205211.Google ScholarPubMed
19Ott, SJ, Musfeldt, M, Wenderoth, DF, Hampe, J, Brant, O, Folsch, UR, Timmis, KN & Schreiber, S (2004) Reduction in diversity of the colonic mucosa associated bacterial microflora in patients with active inflammatory bowel disease. Gut 53, 685693.Google ScholarPubMed
20Swidsinski, A, Ladhoff, A, Pernthaler, A, Swidsinski, S, Loening-Baucke, V, Ortner, M, Weber, J, Hoffmann, U, Schreiber, S, Dietel, M & Lochs, H (2002) Mucosal flora in inflammatory bowel disease. Gastroenterology 122, 4454.CrossRefGoogle ScholarPubMed
21Kleessen, B, Kroesen, AJ, Buhr, HJ & Blaut, M (2002) Mucosal and invading bacteria in patients with inflammatory bowel disease compared with controls. Scand J Gastroenterol 37, 10341041.CrossRefGoogle ScholarPubMed
22Macfarlane, S, Furrie, E, Cummings, JH & Macfarlane, GT (2004) Chemotaxonomic analysis of bacterial populations colonizing the rectal mucosa in patients with ulcerative colitis. Clin Infect Dis 38, 16901699.CrossRefGoogle ScholarPubMed
23Cummings, JH, Antoine, JM, Azpiroz, F, Bourdet-Sicard, R, Brandtzaeg, P, Calder, PC, Gibson, GR, Guarner, F, Isolauri, E, Pannemans, D, Shortt, C, Tuijtelaars, S & Watzl, B (2004) PASSCLAIM–gut health and immunity. Eur J Nutr 43, Suppl 2, 118173.Google ScholarPubMed
24Gibson, GR, Probert, HM, Van Loo, J, Rastall, RA & Roberfroid, MB (2004) Dietary modulation of the human colonic microbiota: updating the concept of prebiotics. Nutr Res Rev 17, 259275.Google ScholarPubMed
25Macfarlane, S, Macfarlane, GT & Cummings, JH (2006) Review Article: prebiotics in the gastrointestinal tract. Aliment Pharmacol Ther. 24, 701714.CrossRefGoogle ScholarPubMed
26Langlands, SJ, Hopkins, MJ, Coleman, N & Cummings, JH (2004) Prebiotic carbohydrates modify the mucosa-associated microflora of the human large bowel. Gut 53, 16101616.CrossRefGoogle ScholarPubMed
27Furrie, E, Macfarlane, S, Kennedy, A, Cummings, JH, Walsh, SV, O'Neil, DA & Macfarlane, GT (2005) Synbiotic therapy (Bifidobacterium longum/Synergy 1) initiates resolution of inflammation in patients with active ulcerative colitis: a randomized controlled pilot trial. Gut 54, 242249.CrossRefGoogle Scholar
28Videla, S, Vilaseca, J, Antolín, M, García-Lafuente, A, Guarner, F, Crespo, E, Casalots, J, Salas, A & Malagelada, JR (2001) Dietary inulin improves distal colitis induced by dextran sodium sulfate in the rat. Am J Gastroenterol 96, 14861493.CrossRefGoogle ScholarPubMed
29Lugea, A, Salas, A, Casalot, J, Guarner, F & Malagelada, JR (2000) Surface hydrophobicity of the rat colonic mucosa is a defensive barrier against macromolecules and toxins. Gut 46, 515521.CrossRefGoogle ScholarPubMed
30Osman, N, Adawi, D, Molin, G, Ahrne, S, Berggren, A & Jeppsson, B (2006) Bifidobacterium infantis strains with and without a combination of oligofructose and inulin (OFI) attenuate inflammation in DSS-induced colitis in rats. BMC Gastroenterol 6, 31.CrossRefGoogle ScholarPubMed
31Cherbut, C, Michel, C & Lecannu, G (2003) The prebiotic characteristics of fructooligosaccharides are necessary for reduction of TNBS-induced colitis in rats. J Nutr 133, 21–27.CrossRefGoogle ScholarPubMed
32Hoentjen, F, Welling, GW, Harmsen, HJM, Zhang, XY, Snart, J, Tannock, GW, Lien, K, Churchill, TA, Lupicki, M & Dieleman, LA (2005) Reduction of colitis by prebiotics in HLA-B27 transgenic rats is associated with microflora changes and immunomodulation. Inflamm Bowel Dis 11, 977985.CrossRefGoogle ScholarPubMed
33Madsen, KL, Doyle, JS, Jewell, LD, Tavernini, MM & Fedorak, RN (1999) Lactobacillus species prevents colitis in interleukin 10 gene–deficient mice. Gastroenterology 116, 11071114.CrossRefGoogle ScholarPubMed
34Rumi, G, Tsubouchi, R, Okayama, M, Kato, S, Mozsik, G & Takeuchi, K (2004) Protective effect of lactulose on dextran sulphate sodium-induced colonic inflammation in rats. Dig Dis Sci 49, 14661472.CrossRefGoogle ScholarPubMed
35Camuesco, D, Peran, L, Comalada, M, Nieto, A, Di Stasi, LC, Rodriguez-Cabezas, ME, Concha, A, Zarzuelo, A & Galvez, J (2005) Preventative effects of lactulose in the trinitrobenzenesulphonic acid model of rat colitis. Inflamm Bowel Dis 11, 265–271.CrossRefGoogle ScholarPubMed
36Welters, CFM, Heineman, E, Thunnissen, BJM, van den Bogaard, AEJM, Soeters, PB & Baeten, CGMI (2002) Effect of dietary inulin supplementation on inflammation of pouch mucosa in patients with an ileal pouch-anal anastomosis. Dis Colon Rectum 45, 621627.CrossRefGoogle ScholarPubMed
37Casellas, F, Borruel, N, Torrejon, A, Varela, E, Antolin, M, Guarner, F & Malagelada, JR (2007) Oral oligofructose-enriched inulin supplementation in acute ulcerative colitis is well tolerated and associated with lowered faecal calprotectin. Aliment Pharmacol Ther 25, 10611067.CrossRefGoogle ScholarPubMed
38Lindsay, JO, Whelan, K, Stagg, AJ, Gobin, P, Al-Hassi, HO, Rayment, N, Kamm, MA, Knight, SC & Forbes, A (2006) Clinical, microbiological, and immunological effects of fructo-oligosaccharide in patients with Crohn's disease. Gut 55, 348–355.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 The faecal microbiota of patients with Crohn's disease contains a reduced proportion of Firmicutes. The graph shows data from Manichanh and coworkers (ref 18) and represents number of phylotypes per division in 6 healthy persons and 6 patients in clinical remission.

Figure 1

Fig. 2 Scores of colonic mucosal lesion (solid columns, left ‘y’ axis) and tissue content of myeloperoxidase (MPO, open columns, right ‘y’ axis), a marker of leukocyte infiltration, in rats with colitis induced by DDS. Daily administration of 400 mg inulin by oral gavage significantly reduced lesion scores and myeloperoxidase content in colonic tissue (see reference 28).

Figure 2

Table 1 Effect of Dietary Inulin Supplementation on Pouchitis Disease Activity Index (PDAI)