We searched for articles published in PubMed, Web of Science, the Cochrane Library, and clinicaltrials.gov with the following MeSH terms for IBD and commensal bacteria: “Microbiota”, “Commensal”, “Dysbiosis”, “IBD”, “Ulcerative colitis”, “Crohn's disease”, “Gastrointestinal immune”. Then, the results were combined using “AND” with studies identified by other keywords such as “Ulcerative colitis”, “Crohn's disease”, “Prebiotics”, “Probiotics”, “Antibiotics”, “Faecal microbiota transplant”, “IBD therapy”, “Meta-analysis”. We enrolled all relevant data up to April 2020 by reviewing the titles and abstracts. The reference lists of relevant articles were also scrutinized.

The methodological quality of the current study includes case reports, cohort studies, random clinical trials (RCTs) and reviews and meta-analysis. The risk of bias in the information included depends on the level of evidence according to the type of study.

The immunologic system is composed of innate and adaptative responses. In the latter are the classical Th1 and Th2 immune response theory where different production of cytokines with interferon-γ (IFN-γ) for Th1 cells to attack intracellular organisms and interleukin (IL)-4, IL-5, and IL-13 for Th2 cells for parasitic infections. Another immunologic pathway with Th17 cells can raise IFN-γ effects that are similar to Th1 response, but also target innate immunity through neutrophil activity and epithelial cells response.7 The cytokine IL-23, an important component in the cascade of Th17 cells acts as an effector of T cell subsets and it is involved in many responses that cause inflammation. CD4+Th17 are not found in the germ-free mouse intestines, showing that are generated according to microbiota and external stimuli. Some reports indicated that Il17A deficient mice caused increased colitis associated to high levels of IFN-γ due to the lack of inhibition of Th1 cells pathway. After all the subsets of T cells are in a steady sate, antigen presentation cells favor development of regulatory T cells (Tregs) that act to suppress inflammation by suppressing effector T cells.8

Intestinal epithelial cells (IECs) and mesenchymal are important as barrier function and host response to infection and tissue damage as well. IECs are not only a barrier but also the beginning of the innate immune response to tissue damage; the balance of immune response is between NF-κB and STAT3 signaling pathways. Different cytokines induce activation, proliferation and inflammation-driven repair pathways in IECs including IL-6, IL-11, and IL-22 through STAT3 signals stimulation.9 The mesenchymal cells underlying IECs in another important component in immune system. NOD2 activation through mesenchymal cells protects against enteric pathogens, and provides differentiation factors for IECs stems cells for repair.10

The gastrointestinal tract has an enriched number of microorganisms that interact with the immune system to produce certain types of signals depending on the entity involved. Different bacteria harbored in the intestine are well tolerated by the immune system because of the host genetic code or a response induced by bacteria; this process is called tolerogenic response.11 The signal between the microbe and the host is reciprocal at several levels and is interconnected by a mutual regulation of development and homeostasis. The detection of disarrays in the components that are related in this interaction between microorganisms and intestinal environment is responsible for a cascade that triggers an inflammatory process. This inflammatory process ends in the abrupt increment of frequency of oncologic, liver, and inmmunoallergic processes, including IBD.12

The microbiome is not constant during the lifespan and changes with age. Every segment of the gastrointestinal tract influences the concentration and type of microbiome.13 Microbiota diversity depends on diet as well. The type of diet influences the plasticity of microorganisms living in the gastrointestinal tract. A diet rich in animal products enhances bile tolerant bacteria (Alistipes, Bilophila, and Bacteroides) and depletes others that metabolize plants, such as Firmicutes.14 The growth dynamics of microbiota is very diverse and includes all kingdoms of organisms, such as prokaryotes, eukaryotes and viruses. The introduction of specialized databases with metagenomics has consistently allowed the classification of more than 30 prokaryotic phyla, finding human eukaryotic microbiome as pathogens, commensals and beneficial organisms, and identifying bacteriophages that keeps the gut in healthy homeostasis.13

The role of different organisms as pathogenic or commensal is still an area of study. Some studies showed specific bacteria that help in several ways in mucin production, such as Akkermansiamuciniphila which changes mucus characteristics that improves barrier function and affects homeostasis. Commensals, such as Faecalibacterium prausnitzii needs an environment enriched with mucin to colonize the intestine. Furthermore, different bacteria byproducts like butyrate, boosts the growth of commensal bacteria.15 Likewise, a few fungal microbiota are considered mycobiota in the gastrointestinal tract; this includes Candida, Saccharomyces, Penicillium, and Aspergillus; however some data argue against fungal colonization and suggest that fungi are not common colonization flora. It is debated whether the fungal microbiota is able to colonize as commensals, like bacteria, or is external contamination from the mouth or diet.16

The progress of genetic profiling, including proteomics, metagenomics, and metabolomics, has contributed to the discovery of the composition of complex microbial communities of not only bacteria, but also many other microorganisms. This can help elucidate the change in microbiota as a cause of diseases.

There are different ways in which bacteria and other microorganisms’ changes can alter composition and functions in IBD. Conventional therapy with corticosteroids, immunomodulators, and biologic therapy might help induce remission; however, there are many alternatives to treat inflammation through modifications in the microbiome environment that further ameliorate dysbiosis.29 It can be divided into traditional methods, methods under development, and novel hypotheses to configure microbiome. First, in the traditional methods the use of probiotics, prebiotics, antibiotics, and combinations of these are included. Thereafter, in the methods under development there are fecal microbiota transplant (FMT) and other novel hypotheses.

The rationale behind probiotics is restoration of the microbial balance, modulation, mucosal protection, and induction of immune responses in IBD.30 The study of probiotics in IBD has many outcomes and is broad. One meta-analysis showed a significant increase in remission rates in patients with active ulcerative colitis (p=0.01) and the rate of remission rates was significantly higher in patients with active UC treated with concomitant probiotics. The probiotic called VSL#3 showed an increased remission rate in mild-to-moderately active UC compared to controls, and a relapse reduction rate in patients with pouchitis.31,32

Another recent meta-analysis including 18 trials revealed that probiotics had different effects in terms of remission in Crohn's disease. Some studies did not find a significant influence in Crohn's disease (p=0.07); however, 3 trials in children with IBD showed the advantage of its use.33 Mice models suggest that Lactobacillus plantarum CBT LP3 can be used as a potent immunomodulator with implications in IBD by decreasing intestinal permeability; however, this needs further confirmation.34 No adverse effects were detected between probiotics and controls in UC treatment.31 Current Cochrane studies do not favor the use of probiotics in CD; however, the last study needs an update with new information about probiotics in CD.35

Prebiotic formulations are food substances that are not digested in the human small bowel and increase selective growth of beneficial bacteria in the colon; a benefit that has not been fully explored in IBD. The basis of providing fiber and prebiotic oligosaccharides to increase the abundance of short-chain fatty acid commensal species is as a therapeutic target with immunoregulatory properties.23 The nondigestible polymers of fructose (fructo-oligosaccharides, FOS) are found naturally and fermented by bifidobacteria and lactobacilli.36

In mice models, it is suggested that colitis is diminished in subjects treated with prebiotics compared to untreated controls, and an increase in the abundance of Bifidobacterium spp, and a decrease of Clostridium cluster XI and C. difficile toxin gene expression are closely related to less chronic intestinal inflammation.37 Another trial in mice showed that side chains of pectin not only increased the levels of prebiotic effects but also downregulated inflammatory cytokines (IL-6).38 The clinical trial with more patients (n=103) demonstrated a lack of clinical benefit in using prebiotic supplementation in active Crohn's disease; however, this warrants further investigation in maintaining remission or other unexplored areas.

Probiotic therapy can be improved by adding a prebiotic; allowing a better substrate for bacterial growth. This combination is called synbiotic. A pilot study showed that combining a probiotic like Bifidobacterium longum and a prebiotic like inulin promotes short-term active clinical UC improvement and decreases inflammatory cytokines, such as TNFα and IL1a.39 Another study showed histological improvement and TNFα levels in biopsies at 3 months40 and that preparations composed of six probiotic strains, and a prebiotic of FOS resulted in decreased inflammatory markers in the synbiotic group. In terms of clinical, serologic, and endoscopic activity levels a statistically significant improvement of synbiotic versus placebo was shown.41

Newer data showed that a combination of Lactobacillus probiotics and prebiotics had a significant effect in remission only in patients with UC (p=0.03) and combination with Saccharomyces boulardii, Lactobacillus, and VSL#3 probiotics in CD could be potentially worthy.33 However, information regarding synbiotic studies has a low number of patients and this precludes making assumptions.

Dysbiosis is an important cause of pathogenesis in IBD and its alteration with the use of antibiotics is a potential therapy; however, based on several studies, antibiotics play a role in the development of IBD by leading to dysbiosis and reducing bacterial diversity.42 There is an upward trend of data in favor of antibiotic use for IBD flare-ups, and no association exists between the use of antibiotics and the development of IBD in early stages of life.43

Regarding active UC, data from meta-analyses suggest that antibiotic use maintain remission in 64% compared to placebo, 48%, favoring its use in UC.44 However, the heterogeneity among studies showed that intravenous antibiotics in the long-term are not helpful in UC activity. Some other studies demonstrate that either antibiotic monotherapy or combinations help to achieve better clinical and endoscopic outcomes at 6 and 12 months.45

In CD, antibiotics are used in treating primary active disease in luminal disease, fistulizing disease, and septic complications such as abscesses or post-operative infections. Information from meta-analyses and Cochrane data suggest that either luminal antibiotics or other type of antibiotics have a modest benefit against active CD and may not be clinically meaningful in the short-term or as maintenance of remission with a clinical endpoint at 52 weeks.46 Moreover, the benefit of using antibiotics with immunomodulators or anti-TNF therapy in CD has little benefit in patients at high risk for recurrence, with weak supporting evidence and a need for further evaluation.47

The use of antibiotics in pouchitis, acute or chronic, has different managements depending on data. A meta-analysis shows that antibiotics induce remission with a rate of 74% in chronic pouchitis (95% CI: 56–93%, p<0.001). Another meta-analysis that included prevention and treatment of pouchitis showed good effectiveness of ciprofloxacin in acute and chronic pouchitis; however, with a low effectiveness of metronidazole. Furthermore, current data in terms of pouchitis prevention is inconclusive, powered studies are needed to determine its effectiveness.48 In chronic pouchitis, antibiotic use promotes microbiome-associated resistant strains. This suggests that new schemes of antibiotic therapy and short-term antibiotic alternation should be used.49

Fecal microbiota transplantation is a process in which a fecal suspension from a healthy individual is transferred to a recipient. This process was originally designed as part of the treatment of refractory Clostridiodes difficile; however, there is robust information about its use in IBD including 9 meta-analyses, 4 RCT, and many cohort studies (Table 1).

The information among meta-analyses is heterogeneous due to the information included and the outcomes reviewed. Induction of remission of active UC with FMT was significantly more effective than placebo in the four published RCT with 28% in the FMT group versus 9% in placebo groups (p=0.64, I2=0%). The latest meta-analysis including 4 RCT and 23 cohort studies, 21% of patient achieved clinical remission (CR) with a high risk of heterogeneity. FMT was associated with clinical improvement and endoscopic remission.50,51 Moreover, FMT is associated with a significant increase in the mucosal gut of immunoregulatory cells and anti-inflammatory metabolism (increase of butanoate) and a reduction of Th17 proinflammatory pathways.52

The first meta-analysis regarding the success of CD in CR showed a pooled estimate of 60.5% (p=0.05; I2=37%); however, a more recent meta-analysis showed a pooled portion of CR of 30% (p<0.01, I2=75%) with moderate heterogeneity and lower than previous data.50,53 The main limitation among studies with CD and FMT is the poor correlation between clinical and endoscopic outcomes and the lack of data in this topic due the low prevalence of CD; most information is from cohort studies and case reports.

When IBD patients are divided into subgroups according to disease severity, information shows that patients with moderate-severe disease from cohort studies could achieve more CR than those with mild-moderate disease; however, in RCT, all patients included had mild-moderate disease severity.50

One of the most important characteristics of FMT is its safety. Common adverse events related to patients treated with FMT included gastrointestinal system diarrhea (13%), abdominal distention/flatulence (11.6%), nausea/vomiting (6.1%), abdominal pain (5.5%) and others. Most of the complications like fever, sore throat, and gastrointestinal complaints were self-limiting lasting 24h. The reports of death and worse outcomes are scarce in the current information.51,54

In terms of preparation of the sample for FMT according to current information, the FMT donor is predominantly a man less than 30-years-old. This could be explained by the higher prevalence of irritable bowel syndrome in women. There is still controversy about the perfect stool donor; in available data, a close relative or friend was chosen. A recent study indicates the importance of matching donors and patients for long-term maintenance of UC; siblings’ relationship has a significantly higher maintenance rate compared with a parent-child relationship.55 Information using mice models suggests a core transferable microbiota is necessary in responders to faecal microbiota transplant in UC to trigger an adequate immune reaction.56 No significant difference exists between using a frozen-stool FMT compared to fresh stool or the delivery route used (either common upper GI or common lower GI) in UC or CD.50 Furthermore, from 338 clinical trials regarding FMT, only 10 studies had the characteristics of FMT therapy in IBD patients. In Table 2 are included the current studies from clinicals about FMT and IBD research. However, more data is needed in RCT and prospective studies to evaluate specific donors’ microbiome characteristics, the diet that FMT donors are eating due to its relevancy in the outcome of this treatment, and specific therapies used in transplanted patients such as mesalazine or biologic because these data are important considerations for future research.

Live biotherapeutic products (LBPs) are a mixture of protective commensal bacteria that modulate inflammation through several levels including interaction with inflammosome and tolerogenic responses. SER-109, a mixture of bacterial spores from 50 bacterial species from healthy donors’ fecal matter shows promise to regulate immune responses and several other trials are underway.57 Furthermore, the precise edition of microbiota composition can ameliorate adverse effects of dysbiosis. Investigational microbe-based immunotherapy called QBECO, formulated from inactivated strains of a gut pathogen showed objective reduction of UC disease pathology by activation of the immune system.58 Other experimental studies in mice showed that the addition of tungstate-mediated microbiota reduced severity of intestinal inflammation.59