The etiology of the chronic and severely debilitating Inflammatory Bowel Diseases (IBD), Crohn disease (CD), and ulcerative colitis (UC), remains poorly understood and incidence rates are increasing, especially in children (1–3). Risk factors associated with IBD include urban lifestyle, lack of greenspace (4), genetic factors, heightened hygiene, dietary factors, and changes in the microbiome (5–11). Gut microbes are critical to human health as they mediate key functions of metabolism and immunity (6, 12). It remains unclear whether the dysbiotic microbial communities associated with IBD are a cause or a consequence of the disease. However, both compositional changes and reduced microbial biodiversity are hallmarks of IBD and can even predict therapy failure in pediatric IBD (13). Alterations in gut microbial composition are often associated with more “proinflammatory” microbes, such as Proteobacteria phylum and Ruminococcus gnavus species, and decreased levels of butyrate-producing bacteria (e.g., Faecalibacterium prausnitzii), which correlated strongly in the presence of disease (10–12). Interestingly, dietary therapy is highly effective for pediatric CD, likely mediated by microbes, but is challenging to complete (14, 15). Increased incidence of IBD has been associated with a Western diet (16), and several studies have demonstrated the influence of diet on the gut microbiota (17–20). A number of fantastic reviews have been recently published (21, 22), illustrating the scientific evidence in support of the role that diet plays in the pathogenesis of IBD. Fibers have attracted specific attention and are generally considered beneficial to gut health. However, the reality is much more complex as some patients describe increased symptoms with fibers (23). Therefore, in the following review we will delve deeper, discussing the specific role of dietary fibers in health, and current evidence of fiber effects in IBD cell lines, animal models, and clinical trials, suggesting reasons why some IBD patients describe a sensitivity and worsening symptoms following fiber consumption.

The term dietary fiber, first coined by Howeler, describes a complex group of non-digestible components of cell walls (Figure 1) (24). The term has grown to include non-starch polysaccharides (e.g., cellulose, pectin), non-carbohydrate-based polymers (e.g., lignan), resistant oligosaccharides (e.g., fructooligosaccharides, galatooligosaccharides), and carbohydrates considered to be of animal origin (e.g., chitin) (25). These dietary fibers can be found in a variety of food sources (Figure 2) and structurally differ in their chain length, linkage type, sugar components, and ability to associate with other chemical compounds (Figure 1) (25). Unlike most dietary components, non-digestible dietary carbohydrates (fiber and resistant starch) can withstand the acidity of the stomach and do not undergo degradation in the human small intestine (26); instead they are fermented by the gut microbiota consortium within the large bowel (Figure 2) where one microbe starts the fermentation and others continue the fermentation process, thereby working together systematically. This microbial consortium role thus highlights the potential implications of dysbiosis, which could alter or even prevent fiber fermentation. The colon houses one of the most complex (over 1,000 species) and highest populated microbiomes in the human body (70% of all microbes in the body) (27–29). Diet has been shown to be a key factor influencing the composition and functions of intestinal microbes, and continues to be examined as a tool in shaping the gut microbiota (30, 31). Studies suggest that while the recommended daily fiber intake from the Institute of Medicine (IOM) ranges from 19–38 g per day, dependent on age and gender (32), typical western diets lack fibers, and typically include roughly 13–20 g of dietary fiber per day, from which the commensal microbes are reliant upon for a source of energy and carbon (33–35). Most of the dietary fibers we consume originate from plant cell walls making up fruits, vegetables, and whole grains (25, 36). Dietary fibers consist of a variety of linked monosaccharides creating a variety of diverse molecules with varying side chains and physical variations, including physical arrangement and solubility (25). While these dietary fibers can be classified in a number of ways (37–40), the most common method of classification for nutritional purposes in humans segregates dietary fibers as water-soluble or insoluble (40). Water solubility within the gastrointestinal tract is related to the degree of fermentation by gut microbes (41). Soluble dietary fibers can increase digesta viscosity, which in turn delays gastric emptying and nutrient release, thus reducing glycaemic response (40, 42, 43). Examples of soluble dietary fibers include pectin, arabinoxylan, β-glucans, inulin, fructo-oligosaccharides, galacto-oligosaccharides, and xyloglucans (36). Insoluble dietary fibers, such as cellulose and lignin, on the other hand, are considered to be less valuable to the gut microbes as their strong hydrogen-binding networks reduce their accessible surface area to allow for fermentation (44). The complex structures of these dietary fibers require specific enzymes, such as carbohydrate-active enzymes (CAZymes) found only in microorganisms for degradation and utilization (25, 45). There are over 120 CAZenzymes identified to date, which have been shown to cleave glycosidic linkages (25). A number of key enzymes are highlighted in Figure 1, including those that target the breakdown of arabinoxylan (46), β-fructans (47, 48), cellulose (48), pectin (48), and lignin (49).

A variety of different microbes, that are able to utilize the same dietary fibers, coexist within the human bowel, resulting in a competitive environment that drives a variety of outcomes, based on the utility of these fibers (50). These selective differences in the microbiome of individuals results in distinct bacterial responses to consumption of dietary fibers (51, 52). Studies have demonstrated that this is likely because fermentation of dietary fibers is dependent on microbial community composition, wherein key microbes must be present for fermentation by their partner organisms to take place (52–55).

The human gut microbiome consists of at least 7 key phyla, predominated by Firmicutes (60–90%), Bacteroidetes (8–28%), Proteobacteria (0.1–8%), and Actinobacteria (2.5–5%) (56, 57). Studies suggest that a number of Bacteroidetes are involved in the breakdown of larger polysaccharides into smaller sugars, which can be utilized by Firmicutes that act as cross-feeders for other microbes (44). These microbes utilize a variety of complex pathways in the breakdown of dietary fibers to byproducts essential for human health. Fiber fermentation produces byproducts, such as short chain fatty acids (SCFAs) (58–63). Enzymes such as polysaccharidases, glycosidases, proteases, and peptidases are utilized to break complex carbohydrates or fibers into their sugar and amino acid components before fermenting these smaller components into SCFA, carboxylic acids, CO₂, and H₂ (64, 65).

The primary SCFAs produced by fiber fermentation include acetate, butyrate, and propionate, which have been generally shown to benefit the host through many mechanisms, including providing energy for colonic mucosa cells, reducing inflammation in IBD, and promoting differentiation and apoptosis of colonic cancer cells (66–68). A recent review by Williams et al. provides an excellent overview of the health benefits of these byproducts in humans (36). The precise mechanisms underlying the coordinated multi-microbe breakdown of dietary fibers into their byproducts and subsequent uptake within the gut continues to be illuminated in various healthy host settings. Changes in fermentation processes carry the potential to regulate changes in the gut microenvironment (60), immune modulation (69), and altered energy metabolism (70).

Interestingly, fiber-rich diets are associated with healthy growth of specific commensal microorganisms (71–76), many of which are directly responsible for SCFA production, improved gut mucosal barrier, and preventing inflammation. The amount and rate of SCFA production is dependent on the species and amounts of microbiota present within the gut (77), further illustrating how an altered gut microbiome in the presence of IBD impacts the production and absorption of protective SCFAs.

Although there is consistent evidence to support the general concept that dietary fibers and their fermentation products are likely beneficial in the setting of IBD (78), it is important to recognize that much of this is an extrapolation of what we know from healthy state and that there are fundamental factors that would challenge this paradigm and potentially impact effects of fibers on IBD. First, fiber intake prior to developing IBD has been linked to risk of disease but having IBD has also been shown to result in changes within the patient's diet (79, 80). The same is true for microbes, which are obviously highly relevant to the impact of fiber on human health; they are thought to play a role in disease pathogenesis, but are clearly altered by having IBD (81). Surveys indicate that many patients (mostly with UC) tend to avoid consumption of dietary fibers (23). Some epidemiological studies, such as the EPIC-IBD cohort study, suggest there are no clear associations found to correlate development with IBD in relation to consumption of either total fiber or fiber from select sources (82). Other clinical studies suggest that long term intake of dietary fiber from fruits, and to a lesser degree, vegetables, reduces the risk of developing CD by up to 40%, with no effect on UC (83). These studies suggest that the protective effect of fiber for CD patients is mainly sourced from fruits and not associated at all with fiber intake sourced from whole grain or legumes (84–86). A restriction of dietary fiber consumption in “humanized” mice increases the consumption of colonic mucosa by colonic microbes, which has been suggested to contribute to reduced mucosa and inflammation in IBD (87). Many of the specific microbes affected by fiber-rich diets have been found to be less abundant in IBD (88–95), supporting the idea that fermentation of fibers may be altered in IBD patients. Additionally, animal studies have demonstrated that dietary fibers can inhibit IBD-associated inflammation (96–98), and clinical trials have shown that SCFA can prevent intestinal atrophy in IBD patients, allowing for tissue recovery (99).

Researchers continue to strive to understand the role that individual dietary fibers play in human health and in IBD patients to better appreciate how manipulating diet in these patients may help to improve clinical outcomes. Patients with ulcerative colitis showed a decrease in serum C-reactive protein (CRP) levels when given a fiber-based prebiotic, as well as a reduction in abdominal pain and cramping (100). A similar study by Fritsch et al. demonstrated a reduction of inflammatory markers and dysbiotic microbiome in patients with ulcerative colitis on a low-fat, high-fiber diet (101). Similarly, mice given a probiotic and fiber-based prebiotic displayed amelioration in disease activity and histological score compared to a prebiotic alone, and a reduction in serum CRP levels (102). Recent studies have shown that Institute of Cancer Research (ICR) mice fed a fiber-free diet displayed shortening of colon length, which was found to be an indicator for IBD, and reduced microbial diversity (103). This indicates that dietary fibers play an important role in mitigating disease severity in IBD patients.

Current studies further support the SCFA butyrate as an anti-inflammatory product of fermentation within the colon that may improve epithelial barrier integrity (104–107). However, it is important to also highlight that there remains contradictory evidence from studies that have shown that butyrate had no benefit in these patients (108, 109). Unfortunately, many clinicians continue to promote reduced fiber consumption, or fiber avoidance altogether, in IBD patients (particularly UC) while there is no evidence to support this as a relevant therapeutic intervention (110, 111). While it remains unclear exactly which factors modulate the health benefits associated with dietary fibers in IBD, results from studies performed to date suggest that modulating diet through prebiotic/probiotic therapies to promote select fiber fermentative microbes may aid in improving IBD patient symptoms.

Key features of the following dietary fibers are summarized in Table 1.

We will first present soluble fibers, followed by insoluble.

Based on the studies published to date, there remains clear evidence for the importance of high intake of dietary fibers overall with no current evidence to support restriction of dietary fibers in patients without intestinal strictures or obstructions (21). However, the benefits of the specific types and sources of dietary fibers remain poorly understood, and the research paradigm has begun to shift toward examining the direct effects of individual fiber types in IBD. As many patients describe a sensitivity to dietary fibers (23), it seems wise to recommend that the increased source of dietary fiber come from those fibers with clear evidence to support anti-inflammatory or preventative effects as speculation remains surrounding the negative impact of certain fibers on patient health during IBD flares (110). A recent review of current literature by Levine and colleagues suggests that there is an acceptable amount of data to support recommended moderate to high amounts of fruit and vegetables in CD patient diets, while there remains insufficient evidence to support these recommendations in UC patients (21). Notably, the evidence we have discussed in the previous sections suggests that gut microbes more readily ferment soluble dietary fibers, and the SCFA, butyrate, seems to be the most beneficial byproduct studied to date, providing a source of carbon and energy for the colon epithelium (204). It could be said that specifically those fibers utilized for the production of increased butyrate should be included in greater quantities in the diet of IBD patients, while due to a lack a consistent evidence to support a beneficial effect in IBD patients, insoluble fiber consumption should perhaps be avoided or reduced, especially for those patients with active disease (21). Specifically, arabinoxylans, β-glucans, β-fructans, and pectins, which are all found in vegetables, fruits, and grains, have been shown to be valuable sources of SCFAs by butyrate-producing microbes (21). So what is the easiest means of increasing consumption of these dietary fibers while limiting insoluble fiber consumption? Food products such as bananas and broccolis, nuts, tomatoes, and carrots, mushrooms, and peeled apples and citrus fruits contain high levels of soluble dietary fibers while limiting insoluble fiber intake (205). It is important to note that the evidence in support of this includes very limited numbers of human studies, and a number of contradictory animal and in vitro studies, however, these recommendations may help certain individuals. Interindividual variability in microbial composition and function will also need to be considered, as further discussed below (118).

With an increasing focus on nutritional interventions, especially in children with Crohn disease, and the interest (but still limited supportive research) on specific use of probiotics and prebiotics in IBD, it is important that we broaden our understanding of how foods affect the bowel, especially in regards to the fiber fermentation processes that occur in the bowel. Results from hundreds of studies to date have demonstrated the ability of select individual microbes or whole microbe cultures, in rats, mice, rabbits, swine, poultry, and even select studies in humans, to manipulate fermentation of dietary fibers (209–213). But how do these in vitro and in vivo studies translate to the complex system of the human bowel? As this review highlighted, differences in microbial composition and dietary factors present can result in substantial differences in host inflammatory response (21). Taking into account that each select microorganism utilizes a variety of different environmental sources from the host diet and microenvironment for carbon and energy, along with the dysbiotic nature of the microbiome of IBD patients, there is a clear possibility that incomplete fermentation, potentially due to dysbiotic microbiome, can result in buildup of pro-inflammatory byproducts such as succinate (214). Evidence also suggests an alternative option; specifically, when macrophage cells are stimulated by lipopolysaccharide (LPS), such as that found on pathobionts, a metabolic shift occurs, resulting in accumulation of succinate (214, 215). This in turn promotes biological pathways responsible for the production of pro-inflammatory cytokines, such as interleukin (IL) 1β, suggesting possible avenues for future therapeutics (66, 216). However, with the right combination of microbes and environmental factors, each of these fiber subtypes have been shown to provide anti-inflammatory benefits as highlighted above. It is important to re-highlight here that the gut microbes work in consort and therefore, it is not just one microbe species performing these fermentative processes in isolation; this adds to the complexity of the gut environment.

HA structured the manuscripts draft. HA and DA constructed all figures. All authors contributed to writing and editing the manuscript.

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.