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Inflammatory bowel disease (IBD). Epidemiology. both occur at the highest incidence in Europe, the United Kingdom, and North America. In North America, incidence rates range from 2.2 to 14.3 cases per 100,000 person-years for UC and from 3.1 to 14.6 cases per 100,000 person-years for CD.
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Epidemiology • both occur at the highest incidence in Europe, the United Kingdom, and North America. • In North America, incidence rates range from 2.2 to 14.3 cases per 100,000 person-years for UC and from 3.1 to 14.6 cases per 100,000 person-years for CD
Epidemiology • The peak age of onset of UC and CD is between 15 and 30 years. • A second peak occurs between the ages of 60 and 80. • The male to female ratio for UC is 1:1 and for CD is 1.1–1.8:1. • UC and CD have two- to fourfold increased frequency in Jewish populations in the United States, Europe, and South Africa
Epidemiology • Urban areas have a higher prevalence of IBD than rural areas • high socioeconomic classes have a higher prevalence than lower socioeconomic classes.
Epidemiology • The risk of UC in smokers is 40% that of nonsmokers. Additionally, former smokers have a 1.7-fold increased risk for UC than people who have never smoked. • In contrast, smoking is associated with a twofold increased risk of CD. • Oral contraceptives are also linked to CD; the odds ratio of CD for oral contraceptive users is about 1.4. • Appendectomy is protective against UC but increases the risk of CD.
Epidemiology • If a patient has IBD, the lifetime risk that a first-degree relative will be affected is ~10%. • If two parents have IBD, each child has a 36% chance of being affected. • In twin studies, 58% of monozygotic twins are concordant for CD and 6% are concordant for UC, whereas 4% of dizygotic twins are concordant for CD and none are concordant for UC. • The risks of developing IBD are higher in first-degree relatives of Jewish versus non–Jewish patients: 7.8% versus 5.2% for CD and 4.5% versus 1.6% for UC. • Anatomic site and clinical type of CD is also concordant within families.
Epidemiology • UC and CD are both associated with Turner's syndrome, and Hermansky-Pudlak syndrome is associated with granulomatous colitis. • Glycogen storage disease type 1b can present with Crohn's-like lesions of the large and small bowel. • Other immunodeficiency disorders, such as hypogammaglobulinemia, selective IgA deficiency, and hereditary angioedema, also exhibit an increased association with IBD.
Etiology and Pathogenesis • IBD is currently considered an inappropriate response to the endogenous microbial flora within the intestine, with or without some component of autoimmunity
Etiology and Pathogenesis • Importantly, the normal intestine contains a large number of immune cells in a chronic state of so-called physiologic inflammation, in which the gut is poised for, but actively restrained from, full immunologic responses. During the course of infections in the normal host, full activation of the gut-associated lymphoid tissue occurs but is rapidly superseded by dampening the immune response and tissue repair. In IBD this process may not be regulated normally.
Genetic Considerations • IBD is a polygenic disorder that gives rise to multiple clinical subgroups within UC and CD. • Genome-wide searches have shown disease-associated loci on many chromosomes. • Some loci are associated with both UC and CD, suggesting some overlap in pathogenesis. • Specific gene associations are mostly undefined; however, several predisposing genes have been identified
Genetic Considerations • CARD15 (caspase-associated recruitment domain containing protein 15) on chromosome 16 is a cytosolic molecule that senses bacterial muramyl dipeptide and regulates intracellular signaling. CARD15 protein is expressed by intestinal epithelial cells, including Paneth cells, monocytes, macrophages, and dendritic cells.
Genetic Considerations • Loss-of-function mutations in CARD15 are highly associated with CD and may account for up to 10% of CD risk. CD-associated CARD15 alleles either allow excess NF- B activation or decreased intestinal antimicrobial activity by diminishing defense in production by Paneth cells. Homozygosity for these mutant alleles confers up to a fortyfold increased risk for fibrostenosing CD, especially in the ileum.
Genetic Considerations • IBD has also been associated with polymorphisms in DLG5 and the IL-23 receptor. • Indeed, patients with IBD and their first-degree relatives may exhibit diminished intestinal epithelial cell barrier function.
Defective Immune Regulation in IBD • The mucosal immune system is normally unreactive to luminal contents due to oral tolerance. When soluble antigens are administered orally rather than subcutaneously or intramuscularly, antigen-specific nonresponsiveness is induced. (TGF- ).
Defective Immune Regulation in IBD • Multiple mechanisms are involved in the induction of oral tolerance and include deletion or anergy of antigen-reactive T cells or activation of CD4+ T cells that suppress gut inflammation through secretion of inhibitory cytokines, such as interleukin (IL) 10 and transforming growth factor
Defective Immune Regulation in IBD • Oral tolerance may be responsible for the lack of immune responsiveness to dietary antigens and the commensal flora in the intestinal lumen. • In IBD this suppression of inflammation is altered, leading to uncontrolled inflammation. The mechanisms of this regulated immune suppression are incompletely known.
The Inflammatory Cascade in IBD • A sequential cascade of inflammatory mediators extends the response. • Inflammatory cytokines, such as IL-1, IL-6, and TNF, promote fibrogenesis, collagen production, activation of tissue metalloproteinases, and the production of other inflammatory mediators; they also activate the coagulation cascade in local blood vessels (e.g., increased production of von Willebrand's factor).
The Inflammatory Cascade in IBD • These cytokines are normally produced in response to infection but are usually turned off or inhibited at the appropriate time to limit tissue damage. • In IBD their activity is not regulated, resulting in an imbalance between the proinflammatory and anti-inflammatory mediators. Therapies such as the 5-ASA (5-aminosalicylic acid) compounds are potent inhibitors of these inflammatory mediators through inhibition of transcription factors such as NF- B that regulate their expression.
Exogenous Factors • multiple pathogens (e.g., Salmonella sp., Shigella sp., Campylobacter sp., Clostridium difficile) may initiate IBD by triggering an inflammatory response that the mucosal immune system may fail to control
Exogenous Factors • Anaerobic organisms, particularly Bacteroides and Clostridia species, and some aerobic species such as Escherichia may be responsible for the induction of inflammation. • Agents that alter the intestinal flora, such as metronidazole, ciprofloxacin, and elemental diets, may improve CD.
Exogenous Factors • CD also responds to fecal diversion, demonstrating the ability of luminal contents to exacerbate disease. • On the other hand, other organisms, so-called probiotics (e.g., Lactobacillus sp., Bifidobacterium sp., Taenia suis, and Saccharomyces boulardii), may inhibit inflammation in animal models and humans. • Psychosocial factors can contribute to worsening of symptoms
Role of infection • The role of infection in the pathogenesis of IBD has been evaluated in two ways: the correlation between specific microorganisms and IBD; and the possible association between acute gastroenteritis and IBD
Role of infection • an association between CD susceptibility and specific infectious agents (eg, measles virus, Mycobacterium paratuberculosis, paramyxovirus) has been suggested but remains unproven
Role of infection • Normal intestinal microflora may contribute to the development of IBD in susceptible individuals. • Consistent with this hypothesis is the observation that animals which are genetically altered to be susceptible to IBD do not develop the disease when raised in a germ-free environment
Role of infection • After excluding patients who had acute gastroenteritis within six months of IBD diagnosis and adjusting for potential confounders, the risk of IBD was significantly increased after an episode of acute gastroenteritis (odds ratio 1.4; 95% CI 1.2-1.7). • In addition, there was an approximate 5-fold increase in IBD risk in persons with a previous diagnosis of irritable bowel syndrome
Role of infection • An increased risk of developing IBD, both CD and UC, was also found in a population-based cohort study of 13,148 patients with documented Salmonella or Campylobacter gastroenteritis when compared to a matched control group (1.2 versus 0.5 percent, hazard ratio 2.9, 95% CI 2.2-3.9) . • This increased risk was highest during the first year after infection, but was observed throughout 15 years of observation.
About 40–50% limited to the rectum and rectosigmoid, 30–40% extending beyond the sigmoid but not involving the whole colon, and 20% have a total colitis. When the whole colon is involved, the inflammation extends 1–2 cm into the terminal ileum in 10–20% of patients. This is called backwash ileitis and is of little clinical significance. normal.
Although variations in macroscopic activity may suggest skip areas, biopsies from normal-appearing mucosa are usually abnormal. Thus, it is important to obtainmultiple biopsies from apparently uninvolved mucosa, whether proximal or distal, during endoscopy.Effective medical therapy can change the appearance of the mucosa such that either skip areas or the entire colon can be microscopically normal
Pathology • mild inflammation, the mucosa is erythematous and has a fine granular surface that resembles sandpaper. • In more severe disease, the mucosa is hemorrhagic, edematous, and ulcerated • In long-standing disease, inflammatory polyps (pseudopolyps) may be present as a result of epithelial regeneration.
Pathology • The mucosa may appear normal in remission, but in patients with many years of disease it appears atrophic and featureless, and the entire colon becomes narrowed and shortened. • Patients with fulminant disease can develop a toxic colitis or megacolon where the bowel wall thins and the mucosa is severely ulcerated; this may lead to perforation.
Ulcerative Colitis Microscopic Features • Histologic findings correlate well with the endoscopic appearance and clinical course of UC. • The process is limited to the mucosa and superficial submucosa, with deeper layers unaffected except in fulminant disease. • Ileal changes in patients with backwash ileitis include villous atrophy and crypt regeneration with increased inflammation, increased neutrophil and mononuclear inflammation in the lamina propria, and patchy cryptitis and crypt abscesses.
UC Vs infectious or acute self-limited colitis • First, the crypt architecture of the colon is distorted; crypts may be bifid and reduced in number, often with a gap between the crypt bases and the muscularis mucosae.
UC Vs infectious or acute self-limited colitis • Second, some patients have basal plasma cells and multiple basal lymphoid aggregates. Mucosal vascular congestion, with edema and focal hemorrhage, and an inflammatory cell infiltrate of neutrophils, lymphocytes, plasma cells, and macrophages may be present. • The neutrophils invade the epithelium, usually in the crypts, giving rise to cryptitis and, ultimately, to crypt abscesses
Crohn's Disease: Macroscopic Features • CD can affect any part of the gastrointestinal (GI) tract from the mouth to the anus. • 30–40% of patients have small bowel disease alone, 40–55% have disease involving both the small and large intestines, and 15–25% have colitis alone. • In the 75% of patients with small intestinal disease, the terminal ileum is involved in 90%. • Unlike UC, the rectum is often spared in CD.
Crohn's Disease: Macroscopic Features • CD is segmental with skip areas in the midst of diseased • Intestine Perirectal fistulas, fissures, abscesses, and anal stenosis are present in one-third of patients with CD, particularly those with colonic involvement. • Rarely, CD may also involve the liver and the pancreas.
Crohn's Disease: Macroscopic Features • Unlike UC, CD is a transmural process. • mild disease, aphthous or small superficial ulcerations characterize • in more active disease, stellate ulcerations fuse longitudinally and transversely to demarcateislands of mucosa that frequently are histologically normal. • This "cobblestone" appearance is characteristic of CD, both endoscopically and by barium radiography. • As in UC, pseudopolyps can form in CD.
Crohn's Disease: Macroscopic Features • Active CD is characterized by focal inflammation and formation of fistula tracts, which resolve by fibrosis and stricturing of the bowel. The bowel wall thickens and becomes narrowed and fibrotic, leading to chronic, recurrent bowel obstructions. Projections of thickened mesentery encase the bowel ("creeping fat"), and serosal and mesenteric inflammation promotes adhesions and fistula formation.
Crohn's Disease: Microscopic Features • The earliest :aphthoid ulcerations and focal crypt abscesses with loose aggregations of macrophages, which form noncaseating granulomas in all layers of the bowel wall. • Granulomas can be seen in lymph nodes, mesentery, peritoneum, liver, and pancreas. • Although granulomas are a pathognomonic feature of CD, they are rarely found on mucosal biopsies. • Surgical resection reveals granulomas in about one-half of cases.
submucosal or subserosal lymphoid aggregates, particularly away from areas of ulceration Gross and microscopic skip areas Transmural inflammation that is accompanied by fissures that penetrate deeply into the bowel wall and sometimes form fistulous tracts or local abscesses. Crohn's Disease: Microscopic Features
Ulcerative ColitisSigns and Symptoms • Diarrhea • Rectal bleeding • Tenesmus • Passage of mucus • Crampy abdominal pain.
Ulcerative ColitisSigns and Symptoms • The severity of symptoms correlates with the extent of disease. • Although UC can present acutely, symptoms usually have been present for weeks to months. • Occasionally, diarrhea and bleeding are so intermittent and mild that the patient does not seek medical attention.
Ulcerative ProctitisSigns and Symptoms • fresh blood or blood-stained mucus, either mixed with stool or streaked onto the surface of a normal or hard stool tenesmus • Urgency with a feeling of incomplete evacuation, but rarely have abdominal pain. • With proctitis or proctosigmoiditis, proximal transit slows, which may account for the constipation commonly seen in patients with distal disease
Ulcerative colitisSigns and Symptoms • When the disease extends beyond the rectum, blood is usually mixed with stool or grossly bloody diarrhea may be noted. • Colonic motility is altered by inflammation with rapid transit through the inflamed intestine. • When the disease is severe, patients pass a liquid stool containing blood, pus, and fecal matter. • Diarrhea is often nocturnal and/or postprandial.
Ulcerative colitisSigns and Symptoms • Although severe pain is not a prominent symptom, some patients with active disease may experience vague lower abdominal discomfort or mild central abdominal cramping. • Severe cramping and abdominal pain can occur with severe attacks of the disease. • Other symptoms in moderate to severe disease include anorexia, nausea, vomiting, fever, and weight loss
Ulcerative colitisSigns and Symptoms • Physical signs of proctitis include a tender anal canal and blood on rectal examination. • With more extensive disease, patients have tenderness to palpation directly over the colon. • Patients with a toxic colitis have severe pain and bleeding, • Megacolon have hepatic tympany. • Both may have signs of peritonitis if a perforation has occurred.
Laboratory, Endoscopic, and Radiographic Features • Rise in acute-phase reactants [C-reactive protein (CRP)],platelet count, erythrocyte sedimentation rate (ESR), and a decrease in hemoglobin. • Proctitis or proctosigmoiditis rarely causes a rise in CRP • Fecal lactoferrin is a highly sensitive and specific marker for detecting intestinal inflammation. • Fecal calprotectin levels correlate well with histologic inflammation, predict relapses, and detect pouchitis.
Laboratory, Endoscopic, and Radiographic Features • In severely ill patients, the serum albumin level will fall rather quickly. • Leukocytosis may be present but is not a specific indicator of disease activity.
Diagnosis • Patient's history • Clinical symptoms • Negative stool examination for bacteria, C. difficile toxin, and ova and parasites; • sigmoidoscopic appearance • Histology of rectal or colonic biopsy specimens