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Gut and Liver is an international journal of gastroenterology, focusing on the gastrointestinal tract, liver, biliary tree, pancreas, motility, and neurogastroenterology. Gut atnd Liver delivers up-to-date, authoritative papers on both clinical and research-based topics in gastroenterology. The Journal publishes original articles, case reports, brief communications, letters to the editor and invited review articles in the field of gastroenterology. The Journal is operated by internationally renowned editorial boards and designed to provide a global opportunity to promote academic developments in the field of gastroenterology and hepatology. +MORE
Yong Chan Lee |
Professor of Medicine Director, Gastrointestinal Research Laboratory Veterans Affairs Medical Center, Univ. California San Francisco San Francisco, USA |
Jong Pil Im | Seoul National University College of Medicine, Seoul, Korea |
Robert S. Bresalier | University of Texas M. D. Anderson Cancer Center, Houston, USA |
Steven H. Itzkowitz | Mount Sinai Medical Center, NY, USA |
All papers submitted to Gut and Liver are reviewed by the editorial team before being sent out for an external peer review to rule out papers that have low priority, insufficient originality, scientific flaws, or the absence of a message of importance to the readers of the Journal. A decision about these papers will usually be made within two or three weeks.
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Correspondence to: Uday C Ghoshal
ORCID https://orcid.org/0000-0003-0221-8495
E-mail udayghoshal@gmail.com
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Gut Liver 2022;16(3):331-340. https://doi.org/10.5009/gnl210208
Published online November 18, 2021, Published date May 15, 2022
Copyright © Gut and Liver.
Following acute gastroenteritis (AGE) due to bacteria, viruses, or protozoa, a subset of patients develop new onset Rome criteria positive irritable bowel syndrome (IBS), called postinfection IBS (PI-IBS). The pooled prevalence of PI-IBS following AGE was 11.5%. PI-IBS is the best natural model that suggests that a subset of patients with IBS may have an organic basis. Several factors are associated with a greater risk of development of PI-IBS following AGE including female sex, younger age, smoking, severity of AGE, abdominal pain, bleeding per rectum, treatment with antibiotics, anxiety, depression, somatization, neuroticism, recent adverse life events, hypochondriasis, extroversion, negative illness beliefs, history of stress, sleep disturbance, and family history of functional gastrointestinal disorders (FGIDs), currently called disorder of gut-brain interaction. Most patients with PI-IBS present with either diarrhea-predominant IBS or the mixed subtype of IBS, and overlap with other FGIDs, such as functional dyspepsia is common. The drugs used to treat non-constipation IBS may also be useful in PI-IBS treatment. Since randomized controlled trials on the efficacy of drugs to treat PI-IBS are rare, more studies are needed on this issue.
Keywords: Gastrointestinal disorders, Enteritis, Dysentery, COVID-19, Tropical sprue
Functional gastrointestinal disorders (FGIDs), including irritable bowel syndrome (IBS), are common conditions globally, both in the community and in clinical practice.1 IBS is associated with significant impairment in quality of life, work productivity, psychological comorbidity, health-care utilization, and economic consequences.2 The pathogenesis of IBS is enigmatic.3 There has been a paradigm shift recently on the pathogenesis of IBS from psychosomatic disorder to micro-organic condition.3 The Rome Foundation experts recognize this in the Rome IV criteria for IBS published in 2016 in which IBS has been considered to be a disorder of “gut-brain interaction” rather than “brain-gut interaction.”4 Of the several pieces of evidence behind considering IBS to be a micro-organic disorder, the development of the condition following an infectious illness, called postinfection IBS (PI-IBS), is the most important one.3,5,6
PI-IBS is diagnosed when new onset Rome-criteria positive IBS develops in an individual after acute gastroenteritis (AGE) characterized by one or more of the following features, (1) diarrhea, (2) vomiting, (3) fever, and (4) a positive stool culture.6 However, these criteria may need to be modified considering the suggestion that the patients with coronavirus disease-19 (COVID-19), which may not always be associated with diarrhea, may also develop PI-IBS.7-9 The pathogenesis of PI-IBS is multifactorial, including the agent, host, and host-agent interaction-related factors.10 The current manuscript plans to review the (1) epidemiology, including risk factors, (2) etiology and pathogenesis, (3) clinical presentation, (4) investigations, (5) management, and (6) prognosis of PI-IBS. It also summarizes the future direction on the subject.
As shown in Table 1, based on data from 29 studies, 3.7% to 85.5% of subjects with AGE due to different causes developed PI-IBS;10-39 this incidence rates were much higher than the development of IBS among the control population in 16 studies (0.3% to 23.3%).10 In a recent meta-analysis, the pooled prevalence of PI-IBS was 11.5% (2,217/21,421; 95% confidence interval, 8.2 to 15.8); the prevalence was comparable in the studies reporting prevalence at 3, 6, 12, 13–59, or ≥60 months after AGE.40 Wide variations in PI-IBS prevalence in different studies are related, at least in part, to the difference in the frequency of various risk factors for PI-IBS development in the diverse patient population.
Table 1 Incidence, Etiology of Acute Gastroenteritis, and Risk Factors for Postinfection IBS in Cases and Controls
Study (year) | Country | Cause of gastroenteritis | IBS in cases (%) | IBS in controls (%) | Risk factors for postinfection IBS |
---|---|---|---|---|---|
McKendrick | UK | 12/38 (31.6) | No control | Severity of acute illness, vomiting and weight loss | |
Gwee | UK | 20/75 (26.6) | No control | Anxiety, depression, somatization, and neurotic trait | |
Neal | UK | Bacteria | 23/347 (6.6) | No control | Longer duration of diarrhea, younger age, and female sex |
Gwee | UK | - | 19/109 (17.4) | Psychological and rectal biopsy: 21 HS | Psychological factors and persistent rectal inflammation |
Rodríguez | UK | Bacteria | 14/318 (4.4) | 2,027/58,4308 (0.3) | Not evaluated |
Mearin | Spain | 31/266 (11.6) | 5/333 (1.5) | No risk factor identified | |
Ilnyckyj | Canada | Traveler’s diarrhea | 2/48 (4.2) | 1/61 (1.6) | Not evaluated |
Dunlop | UK | 103/747 (13.8) | No control | Increased enterochromaffin cells in lamina propria and depression | |
Parry | UK | 18/108 (16.7) | 4/219 (1.9) | Not evaluated | |
Wang | China | 24/295 (8.1) | 2/243 (0.8) | Longer diarrhea, IL-1β mRNA expression and mast cell in ileum and rectosigmoid | |
Okhuysen | USA | Traveler’s diarrhea | 60 (6) | No control | More diarrhea, medical consultation, and stool negative for the pathogen |
Ji | Korea | Shigellosis | 15/101 (14.8) | 6/102 (5.8) | Diarrhea duration |
Parry | UK | Bacteria | 16/107 (15) | No control | Smoking |
Kim | Korea | 13/95 (13.6) | 4/105 (3.8) | Pre-existing FBD other than IBS | |
Marshall | Canada | 417/1,368 (30.5) | 71/701 (10.2) | Young age, female, bloody stools, weight loss, and long diarrhea | |
Borgaonkar | Canada | Bacteria | 7/191 (3.7) | No control | Fever during gastroenteritis |
Stermer | Israel | Traveler’s diarrhea | 16/118 (13.6) | 7/287 (2.4) | Female gender, abdominal pain, long diarrhea, and antibiotic use |
Marshall | Canada | Viral diarrhea | 21/89 (23.6) | 1/29 (3.4) | Vomiting during gastroenteritis |
Spence | New Zealand | 86/581 (14.8) | No control | Psychological comorbidity and lack or rest during gastroenteritis | |
Hanevik | Norway | 66/82 (80.5) | No control | Not evaluated | |
Zanini | Italy | 40/186 (21.5) | 3/198 (1.5) | Not evaluated | |
Cremon | Italy | 75/204 (36.8) | 44/189 (23.3) | Anxiety and functional dyspepsia | |
Persson | Norway | 224/724 (32) | 96/847 (11.4) | Not evaluated | |
Wadhwa | USA | 52/205 (25) | No control | Longer infection duration, current anxiety, and higher BMI | |
Andresen | Germany | Shiga-like toxin-producing | 98/389 (25.3) | No control | Higher somatization and anxiety scores |
Dormond | USA | 16/80 (20.0) | 294 (5.4) | Axis I psychological disorders | |
Rahman | Bangladesh | 57/345 (16.5) | 9/345 (2.6) | Dyspeptic symptoms, continuing bowel dysfunction, and weight loss | |
Parida | India | Yersinia enterocolitica | 35/136 (25.7) | No control | Younger age, prolonged duration of diarrhea and abdominal cramps |
Iacob | Romania | 25/45 (55.5) | 6/45 (13.3) | Female gender, rotavirus and |
IBS, irritable bowel syndrome; HS, healthy subject; IL, interleukin; FBD, functional bowel disease; BMI, body mass index.
Multiple factors have been identified to be associated with a greater risk of developing PI-IBS following AGE. The risk factors for the development of PI-IBS include female sex, younger age, smoking, severity of AGE (including stool frequency and diarrhea duration longer than 1 week), abdominal pain, bleeding per rectum, treatment with antibiotics, anxiety, depression, somatization, neuroticism, recent adverse life events, hypochondriasis, extroversion, negative illness beliefs, history of stress, sleep disturbance, and family history of FGIDs.10,33,40 In one of our studies, we found that the patients who continued to have lower and upper gastrointestinal (GI) symptoms referred to as chronic bowel dysfunction and dyspeptic symptoms during the initial period of follow-up after AGE were more likely to develop IBS and functional dyspepsia after the 6-month cutoff time point, which is required to diagnose these conditions as per the Rome criteria.32,41
In a Canadian study on PI-IBS, the authors developed and validated a risk score.42 For the risk score development, the authors used the risk factors mentioned above, including the demographic and psychological parameters and AGE-related parameters. In addition, they used weight loss of at least 10 lbs (4.5 kg) as one of the parameters. The authors found that if the score was low (score <42), 10% developed PI-IBS. In the intermediate (43–68) and high (>69) score groups, 35% and 60% of AGE patients developed PI-IBS, respectively.42 This scoring system was validated in an Indian cohort, which showed that with a cutoff value of >50, the sensitivity and specificity of the score to predict the development of PI-IBS at 6-month follow-up were 91.4% and 84.2%, respectively.33 Since the different cohorts of AGE patients reported are pretty heterogeneous concerning the above risk factors and the types of the organism causing the gastroenteritis episodes, the wide variation in the prevalence of PI-IBS ranging from 3.7% to 85.5% following AGE is not unexpected.10
As shown in Table 1, infection with bacterial, viral, and protozoal agents causing AGE has been reported to be followed by PI-IBS.11-39 Among bacteria, infection with organisms causing dysentery such as Shigella is more likely to result in PI-IBS than others.10 However, recently, even bacterial pathogens that conventionally do not invade the gut mucosa, such as
PI-IBS less commonly follows viral diarrhea. As shown in Table 2, in the four case-control studies on PI-IBS following viral diarrhea, 0.4% to 12.5% of patients following viral diarrhea developed PI-IBS;24,27,45,46 however, the frequency among viral diarrhea patients was greater than that among the controls. The low frequency of PI-IBS in patients with viral diarrhea is expected; viral agents causing AGE are somewhat less invasive than bacterial agents such as Shigella.
Table 2 Case-Control Studies on PI-IBS Following AGE Due to Viruses
Study (year) | No. of AGE patients | PI-IBS in AGE patients, No. (%) | No. of controls | PI-IBS in controls, No. (%) |
---|---|---|---|---|
Porter | 1,718 | 7 (0.4) | 6,875 | 42 (0.6) |
Zanini | 178 | 14 (7.8) | 198 | 3 (1.5) |
Saps | 44 | 4 (9.1) | 44 | 2 (4.5) |
Marshall | 87 | 11 (12.5) | 29 | 3 (10.3) |
Total | 2,027 | 36 (1.7) | 7,146 | 50 (0.6) |
PI-IBS, postinfection irritable bowel syndrome; AGE, acute gastroenteritis.
An important issue is whether infection with severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2), an RNA virus, originating from the Wuhan city, China, in December 2019, resulting in the devastating pandemic of COVID-19, can cause PI-FGIDs?7 This is not entirely unexpected as angiotensin-converting enzyme-2 (ACE-2) receptors, the binding site of SARS-CoV-2, are also present in intestinal epithelial cells; the virus has been detected in feces in about half of the patients, GI symptoms, including diarrhea occur in about one-fifth of patients, fecal calprotectin, a marker of GI inflammation, and mucosal serotonin are raised in patients with COVID-19, macroscopic as well as histological evidence of GI mucosal injury occur in them, and gut microbiota dysbiosis has been shown to occur in patients with COVID-19.7-9,47-55 Moreover, the SARS-CoV-2 virus has an affinity to involve central and peripheral nervous systems as evidenced by anosmia and ageusia occurrence in 15% to 30% of patients and autopsy findings of marked inflammation of olfactory bulb, cerebrum, and brainstem.53,54 Patients with COVID-19 have also been shown to increased intestinal permeability.56 Moreover, the psychological stress due to the COVID-19 pandemic may be associated with central hypervigilance.55 Fig. 1 summarizes all these putative pathophysiological mechanisms, which may be related to the development of post-COVID-19 FGIDs. Though based on these potential pathophysiological mechanisms, we hypothesized on a possibility of an inevitable surge of post-COVID-19 FGIDs;7 it is yet to be proved by a published study.
The pathogenesis of PI-IBS involves agent, host, and host-agent interaction-related factors. As shown in Tables 1 and 2, the reported frequency of PI-IBS development is highest with protozoa, intermediate with bacteria, and lowest with the viral agents.10 Several host factors interplay with the infectious agent leading to protracted long-term inflammation of the gut, which might be compounded by inadequate T regulatory responses controlling the inflammation.10 Chronic inflammation and altered intestinal permeability have been shown in patients with diarrhea-predominant IBS (IBS-D), including PI-IBS.10,57 In a case-control study in a cohort of 21 AGE patients due to Campylobacter and 12 controls, enteroendocrine cells, CD3, CD4, and CD8 lymphocyte counts in lamina propria and intraepithelial lymphocytes and small intestinal permeability were increased in PI-IBS patients than the controls.58 In a recent systematic review and meta-analysis, small intestinal permeability was more often abnormal among patients with PI-IBS (4/4 studies) and IBS-D (9/13 studies) than those with constipation-predominant IBS (IBS-C; 2/7 studies).59 Lack of down-regulation in the inflammatory response following acute GI infection contributes to the development of PI-IBS. In a study on eight PI-IBS patients, seven with AGE not developing PI-IBS and 18 healthy controls, the patients with PI-IBS exhibited increased inflammatory cell infiltrate and higher levels of interleukin (IL)-1β (a pro-inflammatory cytokine) mRNA in rectal biopsies by reverse transcriptase-polymerase chain reaction even 3 months after AGE compared to the other groups.60 PI-IBS patients have also been shown to have increased levels of peripheral IL-6, pleiotropic cytokine activating inflammatory nuclear factor (NF)-kB transcription pathway, compared to the healthy controls.61,62 Host factors are essential determinant of the protracted inflammatory response following GI infection. Polymorphisms in several pro- and anti-inflammatory cytokine genes increasing and decreasing their responses, respectively, have been shown to play an important role. The Canadian Walkerton cohort polymorphism study revealed a trend towards an association between single nucleotide polymorphisms in the gene involved in the immune and gut epithelial barrier pathways located in TLR9 (encoding pattern recognition receptor [rs352139 and P545P]) and CDH1 (encoding a tight junction protein [rs16260, -C160A], and IL-6 (rs1800795, -G174C) and development of PI-IBS.63 In another study, TNF alpha polymorphism was associated with PI-IBS following
Gut microbiota dysbiosis is another crucial contributor to the development of PI-IBS. Gut microbiota gets altered during the acute phase in patients with AGE66 that may last long after the AGE episode.67 PI-IBS patients have been shown to have unique gut microbiota signature compared to the other IBS patients.68 De Palma
The criteria laid down by the Rome Foundation Working Team on PI-IBS suggest that this condition should be diagnosed when new onset Rome-criteria positive IBS develops in an individual after AGE characterized by two or more of the following features; diarrhea, vomiting, and fever (when stool culture is not available).6 However, it is essential to note that though the Rome Foundation Working Team on PI-IBS suggested using Rome IV criteria for diagnosis of PI-IBS, considering the low sensitivity of Rome IV criteria compared to the Rome III criteria to diagnose IBS,1,73 the latter criteria may also be acceptable.
As Rome criteria require that the symptoms must have started at least 6-month before and the patients must be symptomatic during the last 3 months, many patients continuing to fulfill the Rome criteria for IBS following AGE would not be diagnosed as IBS unless they wait for 6 months to meet the criteria.4,6,41 Hence, we proposed that if the symptoms of IBS are present during the follow-up after AGE, but the subjects did not fulfill the duration criteria suggested by the Rome Foundation, the condition be called chronic bowel dysfunction,32 which the Rome Foundation Working Team has accepted.6
An essential clinical clue to the possibility of PI-IBS comes from the targeted question to the patients “When did the symptom start?” If the patient recalls the date or month, the clinicians should be alert about the possibility of PI-IBS. Most patients with PI-IBS have either IBS-D or mixed type of IBS.40 PI-IBS may have other overlapping FGIDs. In one of our earlier studies, of 66 of 345 AGE patients developing PI-FGIDs, 16 (24%) had overlapping functional dyspepsia.32 Patients may also have other extra-GI symptoms such as psychological comorbidity, sleep dysfunction similar to the other non-PI-IBS.
The investigations in patients with PI-IBS include routine hematology, blood biochemistry, C-reactive protein, fecal calprotectin, and stool microscopy to look for protozoa, such as Giardia.6 However, it is essential to mention that in the presence of severe symptoms, significant weight loss, anorexia, local epidemiology, and the other clinical clues (based even on the results of the initial tests), investigations to rule out other causes of chronic diarrhea such as celiac disease, tropical sprue, microscopic and collagenous colitis, and inflammatory bowel disease are warranted.6 Since about one-tenth of patients with Rome-criteria defined, PI-IBS may have post-infectious malabsorption syndrome (tropical sprue) in tropical countries and visitors to these endemic regions, the investigations for tropical sprue should be undertaken if clinically indicated.32 PI-IBS and tropical sprue are spectrum disorders. The investigations for tropical sprue include D-xylose test, fecal fat excretion, serum vitamin B12 estimation, and endoscopic duodenal biopsy.32 Since a third of patients with tropical sprue and about a fifth of patients with IBS-D have small intestinal bacterial overgrowth (SIBO), a glucose hydrogen breath test may be done as a specialized investigation to diagnose SIBO in patients with PI-IBS.74-76 Pimentel’s group found that anti-cytolethal distending toxin B and anti-vinculin antibodies are helpful in diagnosing IBS-D in general and PI-IBS, in particular among patients with diarrhea.77 Hence, these may be helpful in diagnosis in selected patients.
The data on the treatment of PI-IBS are scanty. Hence, currently, these patients are treated in the same way as any IBS-D patient.6,78 Fig. 2 outlines the drugs which have been found useful or not in the treatment of PI-IBS and the drugs that have been established in the treatment of IBS-D but have not been evaluated for PI-IBS.6,78 The name of drugs for the treatment of IBS-D and their dosages are summarized in Table 3. Though 5-aminosalicylic acid was not found useful in IBS-D in randomized controlled trials, it benefited the subset of patients with PI-IBS.79 In a randomized controlled trial from China, dietary glutamine was found useful in PI-IBS patients.80 Prednisolone and rifaximin were not found useful in PI-IBS.81-83 However, the rifaximin study had several limitations, such as a small sample size, low dose of rifaximin (550 mg twice daily), and use of early peak-criteria on lactulose hydrogen breath test for diagnosis of SIBO, which is known to have poor specificity.82 Since restriction of fermentable oligo-di-mono-saccharide and polyol (FODMAP) diet has been shown helpful in IBS, it is also expected to help patients with PI-IBS.3,78,84 However, there is no study yet on the low FODMAP diet in the management of PI-IBS. Visceral neuromodulators, particularly the tricyclic anti-depressants, are expected to be helpful in the management of PI-IBS as these tend to reduce diarrhea by their anticholinergic activity.3,78 However, no study has been conducted on this issue in patients with PI-IBS. Since other subtypes of IBS such as mixed IBS and even rarely constipation-predominant IBS may occur after AGE, the management of different subtypes of IBS may also be applicable in patients with PI-IBS.3,78
Table 3 Drugs (Including the Dosages) Used in the Treatment of Diarrhea-Predominant Irritable Bowel Syndrome (IBS) That May Also Be Useful in Postinfection IBS
Drug class | Agents | Dose |
---|---|---|
Opiates | Loperamide | 2–4 mg, 4 times per day |
Diphenoxylate | 2.5–5 mg, 4 times per day | |
Eluxadoline | 100 mg twice daily | |
Bile acid modulators | Cholestyramine | 4 g daily or up to 4 times per day |
Colestipol | 4 g daily or up to 4 times per day | |
Colesevelam | 1,875 mg up to twice daily | |
Obeticholic acid | 25 mg per day | |
5HT-3 receptor antagonists | Alosetron | 0.5–1 mg twice daily |
Ondansetron | 2–8 mg twice daily | |
Ramosetron | 5 µg per day | |
Gut microbiota manipulators | ||
Probiotics | ||
Antibiotics | Rifaximin | 550 mg thrice daily for 14 days |
Fiber supplements | Calcium polycarbophil | 5–10 g daily |
Psyllium | 10–20 g daily | |
Pectin | 2 Capsules daily before meal |
The studies showed that the prognosis of PI-IBS patients is generally good as almost half of them recover during the long-term follow-up.85,86 A Korean study showed that though the rates of IBS increased till 3-year, it reduced thereafter. Among the PI-IBS patients, post-viral PI-IBS is more often transient than post-bacterial IBS.87
PI-IBS is a disorder of gut-brain interaction (previously called FGID), which undoubtedly proved that some patients with FGIDs are not entirely functional.3,4 PI-IBS may occur following bacterial, protozoal, and viral AGE.10 Two recent studies, one from Bangladesh and the other from India showed that cholera may be followed by the development of PI-IBS.32,33 A pooled prevalence of PI-IBS was 11.5% after an episode of AGE.40 Most patients with PI-IBS either present as IBS-D or mixed subtype of IBS.40 Overlap of PI-IBS with other FGIDs, mainly, functional dyspepsia is common.32 One-fifth of patients with Rome criteria positive PI-IBS may have PI-malabsorption, popularly known as tropical sprue.32 It is believed that the development of PI-IBS may follow COVID-19.7 However, studies are urgently needed to evaluate the frequency, spectrum, and risk factors for the development of PI-IBS, if any, following COVID-19. Since most patients with PI-IBS presents with the non-constipation type of IBS, the drugs used to treat non-constipation IBS may also be useful in PI-IBS treatment. However, most of these drugs have not been evaluated for the treatment of IBS. Of the four drugs evaluated by randomized controlled trial, prednisolone and rifaximin were found ineffective in PI-IBS treatment.81-83 Dietary glutamine was found useful in the treatment of PI-IBS in a Chinese study.80 5-Aminosalicylic acid undergoing randomized controlled trial was not found useful in IBS-D patients.79 However, in the subgroup of patients with PI-IBS, 5-aminosalicylic acid was found useful in IBS-D patients.79 More studies are needed to evaluate the efficacy of various drugs in the treatment of PI-IBS.
No potential conflict of interest relevant to this article was reported.
Gut and Liver 2022; 16(3): 331-340
Published online May 15, 2022 https://doi.org/10.5009/gnl210208
Copyright © Gut and Liver.
Department of Gastroenterology, Sanjay Gandhi Postgraduate Institute of Medical Sciences, Lucknow, India
Correspondence to:Uday C Ghoshal
ORCID https://orcid.org/0000-0003-0221-8495
E-mail udayghoshal@gmail.com
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Following acute gastroenteritis (AGE) due to bacteria, viruses, or protozoa, a subset of patients develop new onset Rome criteria positive irritable bowel syndrome (IBS), called postinfection IBS (PI-IBS). The pooled prevalence of PI-IBS following AGE was 11.5%. PI-IBS is the best natural model that suggests that a subset of patients with IBS may have an organic basis. Several factors are associated with a greater risk of development of PI-IBS following AGE including female sex, younger age, smoking, severity of AGE, abdominal pain, bleeding per rectum, treatment with antibiotics, anxiety, depression, somatization, neuroticism, recent adverse life events, hypochondriasis, extroversion, negative illness beliefs, history of stress, sleep disturbance, and family history of functional gastrointestinal disorders (FGIDs), currently called disorder of gut-brain interaction. Most patients with PI-IBS present with either diarrhea-predominant IBS or the mixed subtype of IBS, and overlap with other FGIDs, such as functional dyspepsia is common. The drugs used to treat non-constipation IBS may also be useful in PI-IBS treatment. Since randomized controlled trials on the efficacy of drugs to treat PI-IBS are rare, more studies are needed on this issue.
Keywords: Gastrointestinal disorders, Enteritis, Dysentery, COVID-19, Tropical sprue
Functional gastrointestinal disorders (FGIDs), including irritable bowel syndrome (IBS), are common conditions globally, both in the community and in clinical practice.1 IBS is associated with significant impairment in quality of life, work productivity, psychological comorbidity, health-care utilization, and economic consequences.2 The pathogenesis of IBS is enigmatic.3 There has been a paradigm shift recently on the pathogenesis of IBS from psychosomatic disorder to micro-organic condition.3 The Rome Foundation experts recognize this in the Rome IV criteria for IBS published in 2016 in which IBS has been considered to be a disorder of “gut-brain interaction” rather than “brain-gut interaction.”4 Of the several pieces of evidence behind considering IBS to be a micro-organic disorder, the development of the condition following an infectious illness, called postinfection IBS (PI-IBS), is the most important one.3,5,6
PI-IBS is diagnosed when new onset Rome-criteria positive IBS develops in an individual after acute gastroenteritis (AGE) characterized by one or more of the following features, (1) diarrhea, (2) vomiting, (3) fever, and (4) a positive stool culture.6 However, these criteria may need to be modified considering the suggestion that the patients with coronavirus disease-19 (COVID-19), which may not always be associated with diarrhea, may also develop PI-IBS.7-9 The pathogenesis of PI-IBS is multifactorial, including the agent, host, and host-agent interaction-related factors.10 The current manuscript plans to review the (1) epidemiology, including risk factors, (2) etiology and pathogenesis, (3) clinical presentation, (4) investigations, (5) management, and (6) prognosis of PI-IBS. It also summarizes the future direction on the subject.
As shown in Table 1, based on data from 29 studies, 3.7% to 85.5% of subjects with AGE due to different causes developed PI-IBS;10-39 this incidence rates were much higher than the development of IBS among the control population in 16 studies (0.3% to 23.3%).10 In a recent meta-analysis, the pooled prevalence of PI-IBS was 11.5% (2,217/21,421; 95% confidence interval, 8.2 to 15.8); the prevalence was comparable in the studies reporting prevalence at 3, 6, 12, 13–59, or ≥60 months after AGE.40 Wide variations in PI-IBS prevalence in different studies are related, at least in part, to the difference in the frequency of various risk factors for PI-IBS development in the diverse patient population.
Table 1 . Incidence, Etiology of Acute Gastroenteritis, and Risk Factors for Postinfection IBS in Cases and Controls.
Study (year) | Country | Cause of gastroenteritis | IBS in cases (%) | IBS in controls (%) | Risk factors for postinfection IBS |
---|---|---|---|---|---|
McKendrick | UK | 12/38 (31.6) | No control | Severity of acute illness, vomiting and weight loss | |
Gwee | UK | 20/75 (26.6) | No control | Anxiety, depression, somatization, and neurotic trait | |
Neal | UK | Bacteria | 23/347 (6.6) | No control | Longer duration of diarrhea, younger age, and female sex |
Gwee | UK | - | 19/109 (17.4) | Psychological and rectal biopsy: 21 HS | Psychological factors and persistent rectal inflammation |
Rodríguez | UK | Bacteria | 14/318 (4.4) | 2,027/58,4308 (0.3) | Not evaluated |
Mearin | Spain | 31/266 (11.6) | 5/333 (1.5) | No risk factor identified | |
Ilnyckyj | Canada | Traveler’s diarrhea | 2/48 (4.2) | 1/61 (1.6) | Not evaluated |
Dunlop | UK | 103/747 (13.8) | No control | Increased enterochromaffin cells in lamina propria and depression | |
Parry | UK | 18/108 (16.7) | 4/219 (1.9) | Not evaluated | |
Wang | China | 24/295 (8.1) | 2/243 (0.8) | Longer diarrhea, IL-1β mRNA expression and mast cell in ileum and rectosigmoid | |
Okhuysen | USA | Traveler’s diarrhea | 60 (6) | No control | More diarrhea, medical consultation, and stool negative for the pathogen |
Ji | Korea | Shigellosis | 15/101 (14.8) | 6/102 (5.8) | Diarrhea duration |
Parry | UK | Bacteria | 16/107 (15) | No control | Smoking |
Kim | Korea | 13/95 (13.6) | 4/105 (3.8) | Pre-existing FBD other than IBS | |
Marshall | Canada | 417/1,368 (30.5) | 71/701 (10.2) | Young age, female, bloody stools, weight loss, and long diarrhea | |
Borgaonkar | Canada | Bacteria | 7/191 (3.7) | No control | Fever during gastroenteritis |
Stermer | Israel | Traveler’s diarrhea | 16/118 (13.6) | 7/287 (2.4) | Female gender, abdominal pain, long diarrhea, and antibiotic use |
Marshall | Canada | Viral diarrhea | 21/89 (23.6) | 1/29 (3.4) | Vomiting during gastroenteritis |
Spence | New Zealand | 86/581 (14.8) | No control | Psychological comorbidity and lack or rest during gastroenteritis | |
Hanevik | Norway | 66/82 (80.5) | No control | Not evaluated | |
Zanini | Italy | 40/186 (21.5) | 3/198 (1.5) | Not evaluated | |
Cremon | Italy | 75/204 (36.8) | 44/189 (23.3) | Anxiety and functional dyspepsia | |
Persson | Norway | 224/724 (32) | 96/847 (11.4) | Not evaluated | |
Wadhwa | USA | 52/205 (25) | No control | Longer infection duration, current anxiety, and higher BMI | |
Andresen | Germany | Shiga-like toxin-producing | 98/389 (25.3) | No control | Higher somatization and anxiety scores |
Dormond | USA | 16/80 (20.0) | 294 (5.4) | Axis I psychological disorders | |
Rahman | Bangladesh | 57/345 (16.5) | 9/345 (2.6) | Dyspeptic symptoms, continuing bowel dysfunction, and weight loss | |
Parida | India | Yersinia enterocolitica | 35/136 (25.7) | No control | Younger age, prolonged duration of diarrhea and abdominal cramps |
Iacob | Romania | 25/45 (55.5) | 6/45 (13.3) | Female gender, rotavirus and |
IBS, irritable bowel syndrome; HS, healthy subject; IL, interleukin; FBD, functional bowel disease; BMI, body mass index..
Multiple factors have been identified to be associated with a greater risk of developing PI-IBS following AGE. The risk factors for the development of PI-IBS include female sex, younger age, smoking, severity of AGE (including stool frequency and diarrhea duration longer than 1 week), abdominal pain, bleeding per rectum, treatment with antibiotics, anxiety, depression, somatization, neuroticism, recent adverse life events, hypochondriasis, extroversion, negative illness beliefs, history of stress, sleep disturbance, and family history of FGIDs.10,33,40 In one of our studies, we found that the patients who continued to have lower and upper gastrointestinal (GI) symptoms referred to as chronic bowel dysfunction and dyspeptic symptoms during the initial period of follow-up after AGE were more likely to develop IBS and functional dyspepsia after the 6-month cutoff time point, which is required to diagnose these conditions as per the Rome criteria.32,41
In a Canadian study on PI-IBS, the authors developed and validated a risk score.42 For the risk score development, the authors used the risk factors mentioned above, including the demographic and psychological parameters and AGE-related parameters. In addition, they used weight loss of at least 10 lbs (4.5 kg) as one of the parameters. The authors found that if the score was low (score <42), 10% developed PI-IBS. In the intermediate (43–68) and high (>69) score groups, 35% and 60% of AGE patients developed PI-IBS, respectively.42 This scoring system was validated in an Indian cohort, which showed that with a cutoff value of >50, the sensitivity and specificity of the score to predict the development of PI-IBS at 6-month follow-up were 91.4% and 84.2%, respectively.33 Since the different cohorts of AGE patients reported are pretty heterogeneous concerning the above risk factors and the types of the organism causing the gastroenteritis episodes, the wide variation in the prevalence of PI-IBS ranging from 3.7% to 85.5% following AGE is not unexpected.10
As shown in Table 1, infection with bacterial, viral, and protozoal agents causing AGE has been reported to be followed by PI-IBS.11-39 Among bacteria, infection with organisms causing dysentery such as Shigella is more likely to result in PI-IBS than others.10 However, recently, even bacterial pathogens that conventionally do not invade the gut mucosa, such as
PI-IBS less commonly follows viral diarrhea. As shown in Table 2, in the four case-control studies on PI-IBS following viral diarrhea, 0.4% to 12.5% of patients following viral diarrhea developed PI-IBS;24,27,45,46 however, the frequency among viral diarrhea patients was greater than that among the controls. The low frequency of PI-IBS in patients with viral diarrhea is expected; viral agents causing AGE are somewhat less invasive than bacterial agents such as Shigella.
Table 2 . Case-Control Studies on PI-IBS Following AGE Due to Viruses.
Study (year) | No. of AGE patients | PI-IBS in AGE patients, No. (%) | No. of controls | PI-IBS in controls, No. (%) |
---|---|---|---|---|
Porter | 1,718 | 7 (0.4) | 6,875 | 42 (0.6) |
Zanini | 178 | 14 (7.8) | 198 | 3 (1.5) |
Saps | 44 | 4 (9.1) | 44 | 2 (4.5) |
Marshall | 87 | 11 (12.5) | 29 | 3 (10.3) |
Total | 2,027 | 36 (1.7) | 7,146 | 50 (0.6) |
PI-IBS, postinfection irritable bowel syndrome; AGE, acute gastroenteritis..
An important issue is whether infection with severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2), an RNA virus, originating from the Wuhan city, China, in December 2019, resulting in the devastating pandemic of COVID-19, can cause PI-FGIDs?7 This is not entirely unexpected as angiotensin-converting enzyme-2 (ACE-2) receptors, the binding site of SARS-CoV-2, are also present in intestinal epithelial cells; the virus has been detected in feces in about half of the patients, GI symptoms, including diarrhea occur in about one-fifth of patients, fecal calprotectin, a marker of GI inflammation, and mucosal serotonin are raised in patients with COVID-19, macroscopic as well as histological evidence of GI mucosal injury occur in them, and gut microbiota dysbiosis has been shown to occur in patients with COVID-19.7-9,47-55 Moreover, the SARS-CoV-2 virus has an affinity to involve central and peripheral nervous systems as evidenced by anosmia and ageusia occurrence in 15% to 30% of patients and autopsy findings of marked inflammation of olfactory bulb, cerebrum, and brainstem.53,54 Patients with COVID-19 have also been shown to increased intestinal permeability.56 Moreover, the psychological stress due to the COVID-19 pandemic may be associated with central hypervigilance.55 Fig. 1 summarizes all these putative pathophysiological mechanisms, which may be related to the development of post-COVID-19 FGIDs. Though based on these potential pathophysiological mechanisms, we hypothesized on a possibility of an inevitable surge of post-COVID-19 FGIDs;7 it is yet to be proved by a published study.
The pathogenesis of PI-IBS involves agent, host, and host-agent interaction-related factors. As shown in Tables 1 and 2, the reported frequency of PI-IBS development is highest with protozoa, intermediate with bacteria, and lowest with the viral agents.10 Several host factors interplay with the infectious agent leading to protracted long-term inflammation of the gut, which might be compounded by inadequate T regulatory responses controlling the inflammation.10 Chronic inflammation and altered intestinal permeability have been shown in patients with diarrhea-predominant IBS (IBS-D), including PI-IBS.10,57 In a case-control study in a cohort of 21 AGE patients due to Campylobacter and 12 controls, enteroendocrine cells, CD3, CD4, and CD8 lymphocyte counts in lamina propria and intraepithelial lymphocytes and small intestinal permeability were increased in PI-IBS patients than the controls.58 In a recent systematic review and meta-analysis, small intestinal permeability was more often abnormal among patients with PI-IBS (4/4 studies) and IBS-D (9/13 studies) than those with constipation-predominant IBS (IBS-C; 2/7 studies).59 Lack of down-regulation in the inflammatory response following acute GI infection contributes to the development of PI-IBS. In a study on eight PI-IBS patients, seven with AGE not developing PI-IBS and 18 healthy controls, the patients with PI-IBS exhibited increased inflammatory cell infiltrate and higher levels of interleukin (IL)-1β (a pro-inflammatory cytokine) mRNA in rectal biopsies by reverse transcriptase-polymerase chain reaction even 3 months after AGE compared to the other groups.60 PI-IBS patients have also been shown to have increased levels of peripheral IL-6, pleiotropic cytokine activating inflammatory nuclear factor (NF)-kB transcription pathway, compared to the healthy controls.61,62 Host factors are essential determinant of the protracted inflammatory response following GI infection. Polymorphisms in several pro- and anti-inflammatory cytokine genes increasing and decreasing their responses, respectively, have been shown to play an important role. The Canadian Walkerton cohort polymorphism study revealed a trend towards an association between single nucleotide polymorphisms in the gene involved in the immune and gut epithelial barrier pathways located in TLR9 (encoding pattern recognition receptor [rs352139 and P545P]) and CDH1 (encoding a tight junction protein [rs16260, -C160A], and IL-6 (rs1800795, -G174C) and development of PI-IBS.63 In another study, TNF alpha polymorphism was associated with PI-IBS following
Gut microbiota dysbiosis is another crucial contributor to the development of PI-IBS. Gut microbiota gets altered during the acute phase in patients with AGE66 that may last long after the AGE episode.67 PI-IBS patients have been shown to have unique gut microbiota signature compared to the other IBS patients.68 De Palma
The criteria laid down by the Rome Foundation Working Team on PI-IBS suggest that this condition should be diagnosed when new onset Rome-criteria positive IBS develops in an individual after AGE characterized by two or more of the following features; diarrhea, vomiting, and fever (when stool culture is not available).6 However, it is essential to note that though the Rome Foundation Working Team on PI-IBS suggested using Rome IV criteria for diagnosis of PI-IBS, considering the low sensitivity of Rome IV criteria compared to the Rome III criteria to diagnose IBS,1,73 the latter criteria may also be acceptable.
As Rome criteria require that the symptoms must have started at least 6-month before and the patients must be symptomatic during the last 3 months, many patients continuing to fulfill the Rome criteria for IBS following AGE would not be diagnosed as IBS unless they wait for 6 months to meet the criteria.4,6,41 Hence, we proposed that if the symptoms of IBS are present during the follow-up after AGE, but the subjects did not fulfill the duration criteria suggested by the Rome Foundation, the condition be called chronic bowel dysfunction,32 which the Rome Foundation Working Team has accepted.6
An essential clinical clue to the possibility of PI-IBS comes from the targeted question to the patients “When did the symptom start?” If the patient recalls the date or month, the clinicians should be alert about the possibility of PI-IBS. Most patients with PI-IBS have either IBS-D or mixed type of IBS.40 PI-IBS may have other overlapping FGIDs. In one of our earlier studies, of 66 of 345 AGE patients developing PI-FGIDs, 16 (24%) had overlapping functional dyspepsia.32 Patients may also have other extra-GI symptoms such as psychological comorbidity, sleep dysfunction similar to the other non-PI-IBS.
The investigations in patients with PI-IBS include routine hematology, blood biochemistry, C-reactive protein, fecal calprotectin, and stool microscopy to look for protozoa, such as Giardia.6 However, it is essential to mention that in the presence of severe symptoms, significant weight loss, anorexia, local epidemiology, and the other clinical clues (based even on the results of the initial tests), investigations to rule out other causes of chronic diarrhea such as celiac disease, tropical sprue, microscopic and collagenous colitis, and inflammatory bowel disease are warranted.6 Since about one-tenth of patients with Rome-criteria defined, PI-IBS may have post-infectious malabsorption syndrome (tropical sprue) in tropical countries and visitors to these endemic regions, the investigations for tropical sprue should be undertaken if clinically indicated.32 PI-IBS and tropical sprue are spectrum disorders. The investigations for tropical sprue include D-xylose test, fecal fat excretion, serum vitamin B12 estimation, and endoscopic duodenal biopsy.32 Since a third of patients with tropical sprue and about a fifth of patients with IBS-D have small intestinal bacterial overgrowth (SIBO), a glucose hydrogen breath test may be done as a specialized investigation to diagnose SIBO in patients with PI-IBS.74-76 Pimentel’s group found that anti-cytolethal distending toxin B and anti-vinculin antibodies are helpful in diagnosing IBS-D in general and PI-IBS, in particular among patients with diarrhea.77 Hence, these may be helpful in diagnosis in selected patients.
The data on the treatment of PI-IBS are scanty. Hence, currently, these patients are treated in the same way as any IBS-D patient.6,78 Fig. 2 outlines the drugs which have been found useful or not in the treatment of PI-IBS and the drugs that have been established in the treatment of IBS-D but have not been evaluated for PI-IBS.6,78 The name of drugs for the treatment of IBS-D and their dosages are summarized in Table 3. Though 5-aminosalicylic acid was not found useful in IBS-D in randomized controlled trials, it benefited the subset of patients with PI-IBS.79 In a randomized controlled trial from China, dietary glutamine was found useful in PI-IBS patients.80 Prednisolone and rifaximin were not found useful in PI-IBS.81-83 However, the rifaximin study had several limitations, such as a small sample size, low dose of rifaximin (550 mg twice daily), and use of early peak-criteria on lactulose hydrogen breath test for diagnosis of SIBO, which is known to have poor specificity.82 Since restriction of fermentable oligo-di-mono-saccharide and polyol (FODMAP) diet has been shown helpful in IBS, it is also expected to help patients with PI-IBS.3,78,84 However, there is no study yet on the low FODMAP diet in the management of PI-IBS. Visceral neuromodulators, particularly the tricyclic anti-depressants, are expected to be helpful in the management of PI-IBS as these tend to reduce diarrhea by their anticholinergic activity.3,78 However, no study has been conducted on this issue in patients with PI-IBS. Since other subtypes of IBS such as mixed IBS and even rarely constipation-predominant IBS may occur after AGE, the management of different subtypes of IBS may also be applicable in patients with PI-IBS.3,78
Table 3 . Drugs (Including the Dosages) Used in the Treatment of Diarrhea-Predominant Irritable Bowel Syndrome (IBS) That May Also Be Useful in Postinfection IBS.
Drug class | Agents | Dose |
---|---|---|
Opiates | Loperamide | 2–4 mg, 4 times per day |
Diphenoxylate | 2.5–5 mg, 4 times per day | |
Eluxadoline | 100 mg twice daily | |
Bile acid modulators | Cholestyramine | 4 g daily or up to 4 times per day |
Colestipol | 4 g daily or up to 4 times per day | |
Colesevelam | 1,875 mg up to twice daily | |
Obeticholic acid | 25 mg per day | |
5HT-3 receptor antagonists | Alosetron | 0.5–1 mg twice daily |
Ondansetron | 2–8 mg twice daily | |
Ramosetron | 5 µg per day | |
Gut microbiota manipulators | ||
Probiotics | ||
Antibiotics | Rifaximin | 550 mg thrice daily for 14 days |
Fiber supplements | Calcium polycarbophil | 5–10 g daily |
Psyllium | 10–20 g daily | |
Pectin | 2 Capsules daily before meal |
The studies showed that the prognosis of PI-IBS patients is generally good as almost half of them recover during the long-term follow-up.85,86 A Korean study showed that though the rates of IBS increased till 3-year, it reduced thereafter. Among the PI-IBS patients, post-viral PI-IBS is more often transient than post-bacterial IBS.87
PI-IBS is a disorder of gut-brain interaction (previously called FGID), which undoubtedly proved that some patients with FGIDs are not entirely functional.3,4 PI-IBS may occur following bacterial, protozoal, and viral AGE.10 Two recent studies, one from Bangladesh and the other from India showed that cholera may be followed by the development of PI-IBS.32,33 A pooled prevalence of PI-IBS was 11.5% after an episode of AGE.40 Most patients with PI-IBS either present as IBS-D or mixed subtype of IBS.40 Overlap of PI-IBS with other FGIDs, mainly, functional dyspepsia is common.32 One-fifth of patients with Rome criteria positive PI-IBS may have PI-malabsorption, popularly known as tropical sprue.32 It is believed that the development of PI-IBS may follow COVID-19.7 However, studies are urgently needed to evaluate the frequency, spectrum, and risk factors for the development of PI-IBS, if any, following COVID-19. Since most patients with PI-IBS presents with the non-constipation type of IBS, the drugs used to treat non-constipation IBS may also be useful in PI-IBS treatment. However, most of these drugs have not been evaluated for the treatment of IBS. Of the four drugs evaluated by randomized controlled trial, prednisolone and rifaximin were found ineffective in PI-IBS treatment.81-83 Dietary glutamine was found useful in the treatment of PI-IBS in a Chinese study.80 5-Aminosalicylic acid undergoing randomized controlled trial was not found useful in IBS-D patients.79 However, in the subgroup of patients with PI-IBS, 5-aminosalicylic acid was found useful in IBS-D patients.79 More studies are needed to evaluate the efficacy of various drugs in the treatment of PI-IBS.
No potential conflict of interest relevant to this article was reported.
Table 1 Incidence, Etiology of Acute Gastroenteritis, and Risk Factors for Postinfection IBS in Cases and Controls
Study (year) | Country | Cause of gastroenteritis | IBS in cases (%) | IBS in controls (%) | Risk factors for postinfection IBS |
---|---|---|---|---|---|
McKendrick | UK | 12/38 (31.6) | No control | Severity of acute illness, vomiting and weight loss | |
Gwee | UK | 20/75 (26.6) | No control | Anxiety, depression, somatization, and neurotic trait | |
Neal | UK | Bacteria | 23/347 (6.6) | No control | Longer duration of diarrhea, younger age, and female sex |
Gwee | UK | - | 19/109 (17.4) | Psychological and rectal biopsy: 21 HS | Psychological factors and persistent rectal inflammation |
Rodríguez | UK | Bacteria | 14/318 (4.4) | 2,027/58,4308 (0.3) | Not evaluated |
Mearin | Spain | 31/266 (11.6) | 5/333 (1.5) | No risk factor identified | |
Ilnyckyj | Canada | Traveler’s diarrhea | 2/48 (4.2) | 1/61 (1.6) | Not evaluated |
Dunlop | UK | 103/747 (13.8) | No control | Increased enterochromaffin cells in lamina propria and depression | |
Parry | UK | 18/108 (16.7) | 4/219 (1.9) | Not evaluated | |
Wang | China | 24/295 (8.1) | 2/243 (0.8) | Longer diarrhea, IL-1β mRNA expression and mast cell in ileum and rectosigmoid | |
Okhuysen | USA | Traveler’s diarrhea | 60 (6) | No control | More diarrhea, medical consultation, and stool negative for the pathogen |
Ji | Korea | Shigellosis | 15/101 (14.8) | 6/102 (5.8) | Diarrhea duration |
Parry | UK | Bacteria | 16/107 (15) | No control | Smoking |
Kim | Korea | 13/95 (13.6) | 4/105 (3.8) | Pre-existing FBD other than IBS | |
Marshall | Canada | 417/1,368 (30.5) | 71/701 (10.2) | Young age, female, bloody stools, weight loss, and long diarrhea | |
Borgaonkar | Canada | Bacteria | 7/191 (3.7) | No control | Fever during gastroenteritis |
Stermer | Israel | Traveler’s diarrhea | 16/118 (13.6) | 7/287 (2.4) | Female gender, abdominal pain, long diarrhea, and antibiotic use |
Marshall | Canada | Viral diarrhea | 21/89 (23.6) | 1/29 (3.4) | Vomiting during gastroenteritis |
Spence | New Zealand | 86/581 (14.8) | No control | Psychological comorbidity and lack or rest during gastroenteritis | |
Hanevik | Norway | 66/82 (80.5) | No control | Not evaluated | |
Zanini | Italy | 40/186 (21.5) | 3/198 (1.5) | Not evaluated | |
Cremon | Italy | 75/204 (36.8) | 44/189 (23.3) | Anxiety and functional dyspepsia | |
Persson | Norway | 224/724 (32) | 96/847 (11.4) | Not evaluated | |
Wadhwa | USA | 52/205 (25) | No control | Longer infection duration, current anxiety, and higher BMI | |
Andresen | Germany | Shiga-like toxin-producing | 98/389 (25.3) | No control | Higher somatization and anxiety scores |
Dormond | USA | 16/80 (20.0) | 294 (5.4) | Axis I psychological disorders | |
Rahman | Bangladesh | 57/345 (16.5) | 9/345 (2.6) | Dyspeptic symptoms, continuing bowel dysfunction, and weight loss | |
Parida | India | Yersinia enterocolitica | 35/136 (25.7) | No control | Younger age, prolonged duration of diarrhea and abdominal cramps |
Iacob | Romania | 25/45 (55.5) | 6/45 (13.3) | Female gender, rotavirus and |
IBS, irritable bowel syndrome; HS, healthy subject; IL, interleukin; FBD, functional bowel disease; BMI, body mass index.
Table 2 Case-Control Studies on PI-IBS Following AGE Due to Viruses
Study (year) | No. of AGE patients | PI-IBS in AGE patients, No. (%) | No. of controls | PI-IBS in controls, No. (%) |
---|---|---|---|---|
Porter | 1,718 | 7 (0.4) | 6,875 | 42 (0.6) |
Zanini | 178 | 14 (7.8) | 198 | 3 (1.5) |
Saps | 44 | 4 (9.1) | 44 | 2 (4.5) |
Marshall | 87 | 11 (12.5) | 29 | 3 (10.3) |
Total | 2,027 | 36 (1.7) | 7,146 | 50 (0.6) |
PI-IBS, postinfection irritable bowel syndrome; AGE, acute gastroenteritis.
Table 3 Drugs (Including the Dosages) Used in the Treatment of Diarrhea-Predominant Irritable Bowel Syndrome (IBS) That May Also Be Useful in Postinfection IBS
Drug class | Agents | Dose |
---|---|---|
Opiates | Loperamide | 2–4 mg, 4 times per day |
Diphenoxylate | 2.5–5 mg, 4 times per day | |
Eluxadoline | 100 mg twice daily | |
Bile acid modulators | Cholestyramine | 4 g daily or up to 4 times per day |
Colestipol | 4 g daily or up to 4 times per day | |
Colesevelam | 1,875 mg up to twice daily | |
Obeticholic acid | 25 mg per day | |
5HT-3 receptor antagonists | Alosetron | 0.5–1 mg twice daily |
Ondansetron | 2–8 mg twice daily | |
Ramosetron | 5 µg per day | |
Gut microbiota manipulators | ||
Probiotics | ||
Antibiotics | Rifaximin | 550 mg thrice daily for 14 days |
Fiber supplements | Calcium polycarbophil | 5–10 g daily |
Psyllium | 10–20 g daily | |
Pectin | 2 Capsules daily before meal |