Gauci, Sammut, Sciberras, Piscopo, Micallef, Cortis, and Ellul:

Introduction

Crohn’s disease (CD) is a lifelong, chronic inflammatory bowel disease (IBD), with a relapsing and remitting nature. The small bowel (SB) is involved to a varying extent in more than two thirds of CD patients. It can run an inflammatory course or a more complicated one with stricture, fistula, and abscess formation [1].

Esophagogastroduodenoscopy (EGD) and ileocolonoscopy with biopsies are the conventional endoscopic techniques that usually enable a diagnosis of IBD. While the duodenal and ileocecal region are usually visualized adequately with these techniques, this may not be the case with other SB segments, because of either their deep location or stricture formation. It has been shown that examination can miss terminal ileal CD, as the latter can skip the distal ileum or involve the submucosal layers and the mesentery [2].

There are various modalities that allow for further assessment of the SB, including radiologic procedures—computed tomographic enterography (CTE), magnetic resonance enterography (MRE) and ultrasonography (US)—and other endoscopic techniques (capsule endoscopy [CE] and enteroscopy). These modalities assist conventional endoscopy in establishing the diagnosis of CD, as well as determining the disease extent, activity and response to therapy. Moreover, radiologic modalities allow for the appreciation of extraintestinal complications. The aim of this review is to analyze the various modalities currently available.

Cross-sectional imaging techniques

Cross sectional imaging techniques: technical issues

Computed tomography (CT)

Conventional abdominopelvic CT has traditionally been used to assess intestinal obstruction and extraintestinal complications of CD, such as abscesses and fistulas. It has a minimal role in the identification of SB CD [3] because of difficulty with the interpretation of collapsed bowel loops, which can hide lesions or simulate pathological wall thickening [4].

CTE and enteroclysis improve visualization of the SB mucosa and wall as they allow for bowel distension, a fundamental requisite for SB imaging [5]. Luminal distension can be achieved with enteric contrast agents, classified as neutral or positive, depending on their X-ray attenuation.

In CTE, contrast is given orally; 1-2 L are usually ingested 30-45 min before the procedure [5]. Neutral contrast agents have X-ray attenuation similar to water. To minimize absorption, water is usually mixed with high molecular size compounds that do not alter water density, such as polyethylene glycol, mannitol, sugar alcohols or sorbitol. Positive contrast agents are usually a mixture of barium sulfate (1-2%) or iodinated contrast agents (2-3%), and are preferred for the evaluation of perforations or fistulas in CD [6]. CT enteroclysis necessitates the placement of a nasojejunal tube under fluoroscopic guidance for enteric contrast administration.

The use of intravenous contrast agents, with imaging after intravenous contrast administration, is mandatory with these techniques. The presence of different contrast enhancement patterns of the bowel wall and the mesenteric vessels will facilitate the assessment of disease activity [7].

CTE has been shown to positively influence the management of patient care with CD [8]. It can assist the diagnosis of SB CD, determine the degree of inflammation, and assess for complications and extraintestinal features.

Magnetic resonance imaging (MRI)

MRE has become an increasingly important imaging modality in the initial assessment of SB CD, as well as in the monitoring of disease activity [9]. MRI can also help in the assessment of perianal disease but this requires a dedicated examination of the pelvis with appropriate high resolution sequences (predominantly short T1 inversion recovery sequences) and is not included in the published/widely used MRE protocols [9].

Acutely inflamed SB segments in CD patients demonstrate increased perfusion and restricted diffusion. Diffusion-weighted imaging (DWI) and dynamic contrast enhanced MRI sequences are both promising techniques for the detection of active SB inflammation and provide quantitative measures of bowel perfusion and diffusion that can differentiate actively inflamed SB segments from normal SB in CD [9,10].

In MRE, oral contrast agents are classified according to the action on the signal intensity of bowel lumen: positive (currently not used), negative and biphasic agents. Negative contrast agents consist of a super-paramagnetic non-absorbable solution of iron oxide particles. These reduce the signal of the intestinal lumen, on both T1- and T2-weighted images, producing a “black lumen” effect [6]. Biphasic contrast agents are water-based agents that contain non-absorbable additives to create a hyperosmolar solution (polyethylene glycol, sorbitol, lactulose, mannitol solutions) that produces a negative effect on T1-weighted and a positive effect on T2-weighted images. This is referred to as a “water-like” effect [6].

When oral contrast is used, a total volume of 1.5 L is usually ingested, and image acquisition should be performed 40-60 min after the ingestion in order to achieve maximal bowel distension [11]. DWI MRE without intravenous contrast material (gadolinium) was found to be non-inferior to contrast-enhanced MRE in the evaluation of SB inflammation in CD [12].

MRE has been shown to alter the management of patients with ileocolonic CD. In a study where patients with ileocolonic CD underwent routine MRE, 53% had additional medical management for previously non-diagnosed active inflammation, while 16% underwent surgery for complicated CD or medical intractability. In all surgical patients, the intraoperative findings were consistent with the MRE diagnosis, demonstrating the reliability of this technique [13].

Another similar study demonstrated that MRE influenced a change in treatment in 55.3% of known CD patients. This included starting immunosuppressants (10.7%), starting or switching anti-tumor necrosis factor-α drugs (27.3%), surgical intervention (10%) and de-escalation in treatment from combined immunosuppressive therapy to monotherapy (2%) [14]. Similarly to CT enteroclysis, MR enteroclysis can also be performed after inserting a nasojejunal tube under radiological guidance.

US

US enables the rapid evaluation of bowel wall thickness and stratification of the bowel located in the right iliac fossa. For a comprehensive entire SB evaluation, the examination time is much longer. Moreover, oral contrast should be used in state-of-the-art whole SB assessment with US [15].

Contrast-enhanced US has been shown to be a useful addition in imaging IBD patients as it can determine disease activity in CD patients with more precision [15]. Intravenous microbubble contrast agents can be used in combination with low mechanical index imaging modes or power Doppler. This will enable better visualization of the vascularity within the thickened bowel walls (>3 mm), assessment of mesenteric lymph nodes, and differentiation between inflammatory and fibrotic strictures [16].

Hence, US also plays an important role in the management of CD patients. One of the drawbacks of US is its reliance on operator experience, not widely available [17].

Cross sectional imaging techniques: findings

Inflammatory activity

The radiological features of underlying active inflammatory CD are presented in Table 1. Bowel-wall thickening >3 mm is defined as abnormal, with thickening >6 mm being classified as severe. Segmental mural hyperenhancement of SB loops relative to normal loops (Fig. 1A,B) correlate significantly with the histological finding of active CD [18,19]. Increased bowel wall vascularization on color Doppler interrogation or contrast-enhanced US is always a sign of active inflammation and has been significantly related to the clinical activity indices [20] and endoscopic activity [21,22] in CD.

Table 1 Radiological features of inflammatory activity

Figure 1 (A) Axial computed tomography (CT) enterogram section shows mucosal hyperenhancement and mural stratification of the actively inflamed distal ileal loops (white arrows), as well as mesenteric hypervascularity adjacent to the involved bowel segment, known as the “comb sign” (black arrow); (B) Coronal CT enterogram section shows multiple enlarged mesenteric lymph nodes (arrow) as well as mesenteric hypervascularity and increased enhancement of the distal ileal loops in keeping with ongoing inflammation; (C) Coronal T2-weighted single-shot fast spin-echo image shows a mural ulcer in an inflamed segment of distal ileum (arrow); (D) Coronal T2-weighted single-shot fast spin-echo image of the abdomen shows fibrofatty proliferation in the right iliac fossa adjacent to a chronically inflamed terminal ileum (arrow), also known as the “creeping fat phenomenon”

Additional signs of mural disease may include ulceration (Fig. 1C) and a “cobblestone” appearance, characteristic of multiple continuous bowel wall ulcerations. Mural stratification entails the visualization of the different layers of the bowel wall (Fig. 1A). When present, the inner mucosa and outer serosa enhance avidly, but the intervening bowel wall can have various degrees of attenuation, depending on what pathological process is present. The presence of intramural edema (target sign) indicates active inflammation, whilst the presence of intramural fat indicates past or chronic inflammation on CTE and MRE [18]. On US, partial or complete loss of the normal gut stratification results in diffuse hypoechogenicity of the bowel wall with a central echogenic line corresponding to the narrowed bowel [23].

A distinct advantage of cross-sectional imaging compared to endoscopy is its ability to evaluate the mesentery. CT density of the mesentery >60 Hounsfield units (HU) is usually defined as severe disease, levels >20 HU but ≤60 HU are classified as mild, and levels ≤20 HU are considered normal [24]. Mesenteric fibrofatty proliferation is seen as finger-like projections of mesenteric fat, which extend towards and encase the anti-mesenteric border of the bowel, resulting in bowel loop separation [23]. Although this “creeping fat phenomenon” (Fig. 1D) is a sign of CD, it persists in clinically quiescent disease [18].

The severity of mesenteric hypervascularity, known as the “comb sign” (Fig. 1A,B), is determined according to the diameter of each vessel. Vessels exhibiting a diameter twice that of normal are usually considered severe, while those with a diameter less than twice the normal diameter, but still with noticeable expansion, are considered mild. This is created by edematous, engorged and hypervascular mesenteric vasa recta vessels, which penetrate the bowel wall perpendicular to the bowel lumen [18]. Engorged vasa recta indicate active inflammation and have been associated with elevated C-reactive protein (CRP) levels and longer hospital stays in patients with severe CD [25].

The presence of enlarged mesenteric lymph nodes (>10 mm) is another feature of active inflammation (Fig. 1B). Intestinal stenosis is classified according to the constitutive narrowness of the intestinal lumen [26]. A lumen >11 mm is defined as normal, <6 mm as severe, with measurements in between 6 and 11 mm being classified as mild [27].

A systematic review comparing MRE and CTE in the evaluation of SB CD demonstrated their role in the correct identification of disease activity. The pooled sensitivity for detecting active SB CD was 87.9% for MRE and 85.6% for CTE. The pooled specificity was 81.2% for MRE and 83.6% for CTE [28]. Another study by Paquet et al demonstrated that the radiological features of wall thickness, mesenteric fat stranding, mesenteric lymphadenopathy and mesenteric abscess positively correlated with the histological inflammatory activity score [29].

Fistulas

Fistulas usually originate from the serosal surface of bowel loops that exhibit signs of active inflammation and connect the diseased bowel to another organ, another bowel segment, or the skin surface. They generally appear as hyperenhancing tracts on CTE and as linear regions of T2 hyperintense signal on MRE. One exception is a perianal fistula (Fig. 2A), often isoattenuating relative to the anorectum, potentially because of its chronicity [18].

Figure 2 (A) Sagittal T2-weighted single-shot fast spin-echoic image of the pelvis shows complex perianal sepsis with two fistulous tracts arising from the anterior and posterior aspect of the anal canal (arrows); (B) Coronal T2-weighted single-shot fast spin-echo image of the abdomen shows two adjacent small bowel loops tethered to each other, indicative of an enteroenteric fistula (arrow), known as the “star-sign”; (C) Coronal computed tomography enterographic section shows a fistula between an inflamed segment of small bowel and the urinary bladder (arrow)

CT and MRI are the preferred imaging tools for the detection of intra-abdominal fistulas [1]. An enteroenteric fistula may appear as an enhanced sinus tract between adjacent bowel loops. A “star sign” (Fig. 2B) represents a conglomerate of inflamed bowel loops interconnected by multiple fistulous tracts. Detection of enterovesical (Fig. 2C) and enterovaginal fistulas can be challenging. This may however be facilitated by the appearance of an air bubble in the urinary bladder or vagina, usually air-free, commonly in proximity to a diseased bowel loop [11].

The sensitivity of CT for the diagnosis of fistulas has been reported in a systematic review. This showed that, based on the pooled results of five studies with surgery and endoscopy as reference standard, the sensitivity was 70% and specificity 97% [10]. Pooled results of four studies with an adequate reference standard (endoscopy and/or surgery) showed a sensitivity of MRI for the diagnosis of fistulas of 76% and specificity of 96% [10].

Abscesses

Abscesses are usually located within the leaves of the mesentery or in the retroperitoneum, often being connected to inflamed bowel by a sinus tract [18]. CT has been reported to determine the exact location and extent of an abscess with great reliability, making it the most useful imaging modality to detect intra-abdominal abscesses in CD (Fig. 3A). One study showed that for the detection of intra-abdominal abscesses the sensitivity, specificity, and accuracy of CT compared with surgical findings were 85.7%, 87.5%, and 87.2%, respectively [30]. In another prospective study, intra-abdominal abscesses were found intraoperatively in 22 patients; the sensitivity of CT for the diagnosis of abscesses was 85% and specificity was 95% [31]. Pooled results from 3 studies, in which surgical findings were used as a reference standard to assess the accuracy of MRI in the detection of abscesses, demonstrated a sensitivity of 86% and a specificity of 93% [32-34].

Figure 3 (A) Axial computed tomography enterogram section shows a thick walled gas and fluid collection (arrow) in the pelvis adjacent to inflamed loops of distal ileum; (B) Coronal T2-weighted single-shot fast spin-echo image of the abdomen shows wall thickening and luminal narrowing of two adjacent segments of distal ileum (arrows) with hypertrophy of the surrounding fat – the latter is suggestive of long-standing inflammatory bowel disease with fibrostenotic disease

Stenotic lesions

Fibrostenotic disease (Fig. 3B) develops in 18-27% of patients with CD within 10-20 years of diagnosis [25,35]. Stenosis is usually defined as thickening of the bowel wall with subsequent narrowing of the SB lumen [1,30]. Depending on the degree of luminal narrowing caused by the stricture, proximal bowel dilatation may be present. In 2 studies comparing CT with endoscopy and surgery, the sensitivity of CT for the detection of stenosis was 85% and 90%, while the specificity was 100% in both [32].

Direct comparison of CT and MRI for the diagnosis of stenosis in a study with 44 patients showed a similar sensitivity (85% vs. 92%) and specificity (100% vs. 90%) [36]. Pooled results of seven studies with adequate reference standard (endoscopy and/or surgery), demonstrated that the sensitivity of MRI for the diagnosis of stenosis was 89% and the specificity was 94% [10]. Better distension was achieved with MR enteroclysis than with MRE, resulting in a higher sensitivity (100% vs. 86%, respectively) and specificity (100% vs. 93%) for detecting stenosis, though the difference was not statistically significant [37]. When CT or MRI is performed before CE, between 27% and 40% of patients are excluded from CE by the identification of a stenosis [38,39].

Contrast-enhanced images of the affected segment demonstrate less prominent enhancement compared with that seen on contrast-enhanced images depicting active inflammation. The enhancement seen with fibrostenotic disease is usually restricted to the mucosa. There is no vasa recta engorgement or reactive lymphadenopathy. Unrestricted diffusion is typically seen on diffusion-weighted images. However, lower apparent diffusion coefficient values have been associated with the degree of fibrosis, with median apparent diffusion coefficient values for fibrotic strictures being lower than those for non-fibrotic strictures [40,41]. Other extraenteric complications of CD identified on cross-sectional imaging include sacroiliitis, renal stones, cholelithiasis, primary sclerosing cholangitis, and lymphoma.

Choice of cross-sectional imaging modality

Enterography vs. enteroclysis

The choice of enterography over enteroclysis is pragmatic. CT and MR enteroclysis probably hold a slight advantage over enterography in the detection of early disease, but more established disease is clearly identified with enterography [17]. Enterography eliminates the technical and logistical difficulties of nasojejunal tube insertion, and it eliminates a potential barrier to patient compliance with future examinations [42]. Although jejunal examination is frequently suboptimal, the ileum, the most common site of SB involvement in CD, is usually well demonstrated using enterography techniques [43].

CTE vs. MRE

The main advantage of MR over CT is the absence of ionizing radiation. Thus MRE is preferentially being utilized for children and young adults who require repeated imaging because of the chronicity of the disease. Other advantages include the ability to obtain a dynamic assessment of the bowel with real-time imaging sequences. Furthermore, MRE also gives an excellent depiction of extraluminal complications of CD, as does CTE [17].

CT is more appropriate in uncooperative patients, because it requires fewer breath holds than MR imaging, thus improving patient compliance. Moreover, CT should be preferred in the emergency setting, because it depicts perforation more accurately and rapidly, and may also reveal the presence of extraintestinal lesions that may be the cause of an acute abdomen [44].

Other advantages of CTE over MRE include its short imaging time and spatial resolution. It allows multiplanar reformation with isovoxel resolution [17] and also guides interventional procedures, such as percutaneous drainage of intra-abdominal abscesses [45]. CT also has a significantly shorter acquisition time, this being 8-10 sec for CTE and 20-30 min for MRE [11].

Limitations of both CTE and MRE include the recognition of fibrotic lesions. While the previously mentioned CTE findings of bowel wall inflammation correlate well with tissue inflammation [46], there is no strong correlation between the radiologic findings presumed to be suggestive of fibrosis and the presence of histological fibrosis. Histological inflammation and fibrosis are strongly correlated with one another, and do not appear to be separable entities [46]. It is in fact likely that CTE and MRE cannot reliably assess the presence of fibrosis with or without associated inflammation, because these two conditions do not exist as mutually exclusive stricture types [46-48].

US vs. MRE

Both US and MRE are ionizing radiation-free imaging modalities. A comparison of US and MRE in CD patients demonstrated a similar sensitivity, specificity, positive predictive value, and negative predictive value for CD diagnosis. The concordance in terms of CD location between the 2 procedures was high (k=0.81). However, US was less accurate than MRE in defining CD extension. Moreover, MRI showed a fair concordance with US regarding the identification of strictures (k=0.82) and abscesses (k=0.88), but better detection of enteroenteric fistulas (k=0.67) [49].

Calabrese et al (2016) demonstrated a sensitivity of 89% and a specificity of 94.3% for US in the assessment of patients with known CD, with lower accuracy for detecting proximal SB lesions. The administration of an oral contrast agent improved the sensitivity and specificity in determining CD lesions [50].

Panes et al showed that MRI had a high diagnostic accuracy for the diagnosis of suspected CD and for evaluation of disease extension and activity (sensitivity 93%, specificity 90%), and was less dependent on the examiner and disease location than US [6].

Radiological scores

There are currently several MRI-based scoring systems that have been developed in comparison to an external reference standard. The Magnetic Resonance Index of Activity (MaRIA) score can assess both SB and colonic segments [51]. The global MaRIA score is calculated as the sum of the segmental MaRIA scores in the ileum, ascending colon, transverse colon, descending colon, sigmoid colon and rectum (Table 2). In the validation study, MRI features of active inflammation were correlated with the CD Endoscopic Index of Severity (CDEIS). Independent predictors for segmental CDEIS were wall thickness (P=0.007), relative contrast enhancement (P=0.01), presence of edema (P=0.02) and presence of ulcers on MRI (P=0.003).

Table 2 Radiological scores

The segmental MaRIA score correlates well with the segmental CDEIS (r=0.82, P<0.001). The overall MaRIA score also correlates with the total CDEIS (r=0.78), CRP levels (r=0.53) and Harvey Bradshaw index (r=0.56). A segmental MaRIA score ≥11 defines severe inflammatory lesions (accuracy 96%) while a MaRIA score <7 detects segmental mucosal healing with reasonable accuracy (83%), sensitivity (85%), and specificity (78%) [51]. It has also been demonstrated that the score correlates well with ulcer healing when MRE is compared to ileocolonoscopy [51]. Potential limitations of the MaRIA score are its failure to take into account the overall length of inflamed segments [51] and its interobserver reproducibility. However, interobserver reproducibility in evaluating inflammation can be improved by modification with DWI [52].

The CD MRI index (CDMI) score (Table 2) was developed through the correlation of MRE findings with transmural histopathology at the time of elective SB surgical resection in CD patients. A simplified model was developed using the MRE parameters that best predicted transmural inflammation [53].

The MRE global score (Table 2) was developed as a modified CDMI to include disease length in order to better capture the full disease burden in CD patients. It was correlated with multiple clinical indices, such as the Harvey Bradshaw index, fecal calprotectin, CRP, and CD activity score [54].

The Nancy Score uses 6 different radiological signs, each recorded in 5 different colonic segments and the ileum, with the total MR score being calculated as the sum of the segmental scores [55]. The Clermont index is similar to the MaRIA score, but includes functional imaging, namely DWI [56]. Another scoring system is the London index. However, when the Clermont index and the London index score were compared to the MaRIA index, the latter had the best operational characteristics for both detecting disease activity and grading severity [57,58]. The creation of similar validated CT scoring systems for CD is in progress.

CE

CE is a noninvasive procedure and allows a direct and detailed evaluation of the SB mucosa with detection of the earliest lesions of CD [58-61].

Mucosal lesions

The mucosal lesions are similar to those seen during EGD and ileocolonoscopy. It should be emphasized that ulcerations (Fig. 4A) detected by CE are not specific for CD [62]. The differential diagnosis includes non-steroidal anti-inflammatory drugs (NSAIDs), lymphoma, radiation enteritis, opportunistic infection in the setting of the human immunodeficiency virus, intestinal tuberculosis, and healthy people [62-64]. It is generally recommended that NSAIDs be stopped four weeks prior to CE; however, the precise period is unknown [61,65]. The presence of more than three ulcerations in patients not using NSAIDs should raise the suspicion of CD [66]. Biopsy of the lesions by means of device-assisted enteroscopy can then provide the histological diagnosis. Goldstein et al demonstrated that 11% of healthy volunteers, not users of NSAIDs, had SB mucosal breaks, and 7% of patients with a normal baseline CE developed 1-3 mucosal breaks after placebo treatment [63].

Figure 4 (A) Small bowel ulcer (arrow) noted on capsule endoscopy with Crohn’s disease being confirmed on biopsies obtained during enteroscopy; (B) Abdominal radiograph demonstrating a retained patency capsule (arrow)

CE vs. cross-sectional imaging

In a meta-analysis, the diagnostic yield of CE in patients with suspected CD was superior to that of SB radiography (52% vs. 16%, P<0.0001) and CTE (68% vs. 21%, P<0.0001) [67]. Compared to MRE, CE had a higher diagnostic yield, but the difference did not reach statistical significance (55% vs. 45%, P=0.43).

Comparing the diagnostic yield of CE in patients with known CD, CE was superior to SB radiography (71% vs. 36%, P<0.00001) and CTE (71% vs. 39%, P<0.0001) with MRE being equal to CE (P=0.65). It should be noted that the studies excluded patients with a radiological suspicion of SB stenosis [67]. In another systematic review, the diagnostic yield of CE was similar to that of MR and US, apart from proximal SB involvement, for which CE seems to be superior (odds ratio 2.62; P=0.03) [68].

Studies have demonstrated that proximal SB involvement is associated with a higher risk of surgery and that jejunal lesions are independent risk factors for future relapse (P=0.02). This superior accuracy may therefore have prognostic value [69].

Assessment of disease activity

Currently there are two validated indices (Tables 3 and 4): the Lewis score and the CE CD Activity Index (CECDAI). There is a good correlation between the two, P<0.0001 [70,71]. For the Lewis score, a level of <135 suggests normal SB or clinically insignificant inflammation; 135-790 means mild disease activity and >790 indicates moderate to severe disease activity [70]. CECDAI levels of 3.8 and 5.8 corresponded to Lewis scores of 135 and 790, respectively [72,73].

Table 3 Lewis score

Table 4 Capsule endoscopy Crohn’s disease activity index

CE and inflammatory markers

Data from small, prospective cohorts suggest that the diagnostic yield of CE is highest in patients with suggestive CD symptoms and elevated inflammatory markers [74,75], although this finding could not be replicated in larger retrospective cohorts [72,76]. Patients with suspected CD who have calprotectin levels <50μg/g have a very low likelihood of positive CE diagnosis (negative predictive value: -91.8%) [77].

Contraindications for CE

Contraindications for CE include gastrointestinal obstruction, strictures and swallowing disorders, although the latter can be overcome by direct endoscopic placement [78,79]. In a comprehensive literature review, capsule retention occurred in 1.5% of patients examined for suspected CD [80,81] and 2-13% of patients with established CD [82].

If SB stenosis is suspected, CE should be preceded by either cross-sectional imaging or a patency capsule (Fig. 4B) so as to avoid capsule retention [65,71]. In a study by Yadav et al, the patency capsule and non-enteroclysis radiologic examinations were equally reliable for excluding SB obstruction or strictures. The advantage of radiologic tests is that they do not depend on intestinal motility, as does the patency capsule. On the other hand, they may overestimate the risk of functional obstruction [83].

Enteroscopy

Traditionally, endoscopic examination of the SB has been challenging [84], though technological advances have extended the reach of the endoscopist, allowing for better access. Enteroscopy has a role in the management of both suspected as well as established CD [64,84], allowing for histological sampling in areas not accessible with the standard EGD and ileocolonoscopy [85]. Its other role is in the form of therapeutic interventions, which include pneumatic dilatation, injection of corticosteroid and immunomodulatory drugs and stent insertion [86,87]. Such therapeutic strategies have resulted in clinical, biochemical and endoscopic improvement in patients with CD [88,89].

Pneumatic dilation is the most common therapeutic use of enteroscopy in CD, and is a valuable alternative to surgical intervention. In a systematic review of 13 retrospective studies published over a 17-year period, Hassan et al demonstrated an 86% technical success rate of pneumatic dilatation in the treatment of strictures due to CD [90]. Long-term clinical efficacy was also evident, as 58% of patients did not require surgery over the follow-up period, a mean of 33 months [90].

Balloon dilatation is indicated for the treatment of non-inflammatory SB strictures of up to 4-6 cm in length [91]. Efficacy is significantly lower in strictures longer than 4 cm [88], and pneumatic dilatation of longer and/or inflammatory strictures has been associated with a significantly increased risk of perforation [91]. Enteroscopy also allows for the retrieval of retained capsules used in wireless CE [91].

Push-and-pull enteroscopy

Push-and-pull enteroscopy is the oldest type of enteroscopy [84]. Its clinical utility and influence on management have been demonstrated in small studies [92,93]. In a study by Darbari et al, push-and-pull enteroscopy confirmed the presence of proximal SB disease in 84% of children with a clinical suspicion of SB pathology [94]. Clinical management was affected in 77% of the pediatric population studied.

Device-assisted enteroscopy (DAE)

DAE is a newer method that allows for the endoluminal examination of the SB by any endoscopic technique that includes assisted progression [84]. The 3 main DAE techniques are double-balloon enteroscopy (DBE), single-balloon enteroscopy (SBE), and spiral enteroscopy (SE).

Balloon-assisted endoscopy (BAE)

BAE involves the stepwise progression of a scope through the small intestine with a balloon-loaded overtube used as a straightening device [84]. The addition of an inflatable balloon at the distal end of the overtube allows for better mucosal grip and stabilizes its position within the intestinal lumen. DBE makes use of a second balloon attached to the tip of the endoscope. If required, complete intubation of the SB is possible, typically through a combined approach through the mouth and the anus [95].

The diagnostic yield of DBE has been shown to influence the management of CD patients [88,89,96]. In a prospective study by Mensink et al, 70% of patients with a clinical suspicion of SB CD were confirmed to have SB CD using this technique [89]. Half of these lesions were inaccessible by conventional endoscopy. The diagnosis achieved with this technique led to a change in therapy in 74% of patients, with a resultant clinical and endoscopic remission in 88% at 1-year follow up [89].

SBE follows the same principles as DBE, except that the tip of the scope is used as an anchor, rather than a second balloon [84,97]. A randomized international multicenter study by Domagk et al was set up to compare the insertion depth of the two techniques. The study revealed a mean insertion depth of 253 cm (DBE) and 258 cm (SBE) with anterograde procedures and a mean insertion depth of 107 cm (DBE) and 118 cm (SBE) with retrograde procedures [97].

Whereas complete visualization of the SB is more likely with DBE (18% vs. 11% of procedures), the diagnostic yield in patients with SB pathology is comparable with both techniques [97]. In a meta-analysis comparing both techniques, DBE was superior to SBE for SB visualization (P=0.004), but had similar rates of providing a diagnosis (P=0.62), therapeutic yield (P=0.09) and complication rate (P=0.9) [98]. Data are limited with regards to comparative studies in CD.

Spiral Enteroscopy (SE)

SE is a newer technique that employs a spiral tipped overtube. This travels ahead of the enteroscope, telescoping the SB and allowing visualization of the mucosa [84]. Likewise, one can insert it both antero- and retrogradely. A recent meta-analysis revealed that the maximum depth of insertion and diagnostic yield is comparable to that of BAE [98], though further comparative studies are required specifically for CD.

Complications

The use of push enteroscopy and diagnostic DAE in the investigation of CD has a complication rate of less than 1%, the main complication being post-procedural abdominal pain, hyperamylasemia and pancreatitis (0.3%) if the oral route is used [99,100]. On the other hand, complication rates of therapeutic DAE are higher in CD [101], Gustavsson et al published the largest study to date on this matter and reported an overall complication rate of 5.3%, though rates were as high as 9.3% with the largest dilatation diameter (25 mm) [101].

Concluding remarks

Small-bowel follow through has been superseded by newer radiological modalities (contrast-enhanced US, MRI, and CT) as well as endoscopic modalities (CE and enteroscopy) in the investigation and management of CD patients. A range of factors determine the choice of modality for SB assessment. These include local availability and expertise, acute vs. non-acute clinical scenarios, patient preference and cooperation during the test. US and MRE should be preferred to CTE because of the absence of ionizing radiation, especially in younger patients. CE should be used with caution when clinical symptoms indicate obstructive or stricturing CD, especially if not preceded by a patency capsule. Enteroscopy allows for histological sampling and therapeutic intervention.

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Small bowel imaging in Crohn’s disease patients

Abstract