Can Computed Tomography Colonography Replace Optical Colonoscopy in Detecting Colorectal Lesions?: State of the Art

Article information

Clin Endosc. 2022;55(2):183-190
Publication date (electronic) : 2022 February 24
doi : https://doi.org/10.5946/ce.2021.254
1Department of Clinical Medicine and Surgery, University of Naples “Federico II”, Naples, Italy
2Department of Advanced Biomedical Sciences, University of Naples “Federico II”, Naples, Italy
Correspondence: Alessia Chini Department of Clinical Medicine and Surgery, “Federico II” University of Naples, Via Sergio Pansini, 5, Naples 80131, Italy Tel: +39-329-212-2828, Fax: +39-081-746-2716, E-mail: alessiachini@hotmail.it
Received 2021 October 11; Revised 2021 November 30; Accepted 2021 December 1.

Abstract

Colorectal cancer is an important cause of morbidity and mortality worldwide. Optical colonoscopy (OC) is widely accepted as the reference standard for the screening of colorectal polyps and cancers, and computed tomography colonography (CTC) is a valid alternative to OC. The purpose of this review was to assess the diagnostic accuracy of OC and CTC for colorectal lesions. A literature search was performed in PubMed, Embase, and Cochrane Library, and 18 articles were included. CTC has emerged in recent years as a potential screening examination with high accuracy for the detection of colorectal lesions. However, the clinical application of CTC as a screening technique is limited because it is highly dependent on the size of the lesions and has poor performance in detecting individual lesions <5 mm or flat lesions, which, although rarely, can have a malignant potential.

INTRODUCTION

Colorectal cancer (CRC) is a major cause of cancer-related morbidity and mortality worldwide, being the fourth most common cause of cancer death and the third most common cancer globally [1]. The major risk factors for CRC are obesity, alcohol consumption, cigarette smoking, and a sedentary lifestyle, and this cancer is more prevalent in Western countries [2]. However, CRC is also increasingly affecting Asian populations. The overall prevalence and incidence of CRC are reported to be lower in Asian than in Western populations, although Asian countries, especially China, Japan, and Korea, have the highest number of prevalent cases [3]. It is widely accepted that most CRCs develop from preexisting adenomatous colon polyps through the adenoma-to-carcinoma sequence, a multistep process that takes many years to complete, during which a sequential accumulation of genetic mutations occur. The transformation from normal epithelium to hyperproliferative mucosa can eventually result in the formation of carcinoma [4,5]. For this reason, colorectal adenomatous polyps are the optimal target lesions for strategies to prevent CRC [6]. The currently available screening tests for CRC are stool-based tests (e.g., stool DNA tests, guaiac-based fecal occult blood test [FOBT], and immunochemical FOBT) and structural examinations (e.g., flexible sigmoidoscopy, optical colonoscopy [OC], double-contrast barium enema, and computed tomography [CT] colonography [CTC], also known as virtual colonoscopy). The colon capsule endoscopy is another technique that allows the evaluation of the whole colon; however, it is not an accepted method for CRC screening [7]. Colonoscopy is widely accepted as the gold standard for the detection of CRC and has the advantage of being both diagnostic and therapeutic because biopsy and resection of polyps or early cancer can be performed during the same procedure. Although OC has a high accuracy in detecting colorectal lesions, it is an invasive technique with a risk of bowel perforation and bleeding. CTC is a good alternative to colonoscopy for CRC screening, as it is a safe and minimally invasive technique that allows the evaluation of the whole colon, including in cases in which OC is not possible to perform [8]; however, some limitations of CTC remain a problem. For example, the total amount of ionizing radiation delivered to patients is a concern, although technological improvements, including the implementation of image reconstruction algorithms and reduction in tube current, have contributed to reducing the associated radiation exposure [9]. Several studies have shown that CTC is comparable to OC in terms of accuracy in detecting polyps and CRC; however, it also presents advantages over OC, such as the certainty of a complete examination and the identification of additional extraluminal pathology. The purpose of this review was to compare OC and CTC in the detection of colorectal lesions, both in asymptomatic average-risk patients and symptomatic high-risk patients.

MATERIALS AND METHODS

To identify all studies that compared OC and CTC in terms of accuracy in detecting colorectal lesions, a comprehensive literature search was conducted in electronic databases (PubMed/MEDLINE, Google Scholar, Embase, and Cochrane Library), according to the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-analyses) guidelines [10], without any restrictions with respect to the publication year. Lists of synonyms for CTC and colonoscopy were produced and combined using the Boolean operator “OR”, and the search results were combined using the Boolean operator “AND”. All types of observational studies that compared CTC and OC for the screening and detection of colorectal polyps, CRC, and advanced neoplasia, both in asymptomatic average-risk patients and symptomatic high-risk patients, restricted to articles written in English, were included in the review. Articles not reporting a comparison between the two techniques, meta-analysis articles, case reports, letters to the editor, and commentaries were excluded. With respect to the details of the two procedures, OC is usually performed by introducing a flexible endoscope through the anus after adequate lubrication and digital inspection of the perianal and rectal regions. Correct endoscope manipulation by the endoscopist in OC allows the exploration, in a retrograde sense, of all segments of the large intestine until the cecum is reached [11]. Meanwhile, CTC uses volumetric CT data produced by a helical CT scanner to generate three-dimensional images displayed in a cine loop, combined with advanced imaging software to generate two-dimensional and three-dimensional images of the colon and rectum. The patient is placed in the left lateral position, and the colon is gently insufflated with air by inserting a Foley catheter in the rectum, according to patient tolerance. Scanning is performed in the prone and supine positions to obtain video sequences similar to those in OC, in two-dimensional and three-dimensional reconstructions. Bowel preparation is required for both CTC and OC. Although good bowel preparation is essential in both procedures, OC has a disadvantage in that the presence of excessive residual fluid hinders the advancement of the colonoscope, whereas CTC does not have this problem. Furthermore, intravenous contrast enhancement in CTC could differentiate residual fluid from colorectal diseases and CRC from inflammatory pathologies, and several studies have shown that intravenous contrast improves the detection of colonic lesions with CTC [12].

RESULTS

The search yielded 1,085 articles, of which 75 were excluded for being duplicates. Two authors independently reviewed the remaining articles by first reading the titles and abstracts. Articles that were not pertinent (not comparing OC and CTC in the detection of colorectal lesions) or not written in English were further excluded. A total of 48 potentially relevant papers were identified, which were retrieved as full-text articles. The reference lists of the final selection of articles were manually checked to identify other relevant papers. Any disagreement was resolved by consensus with a third author (Fig. 1). A total of 18 articles were included in this review. Table 1 reports the characteristics of the included studies: publication year, type of study, number and mean age of the patients included in each study, and whether the patients underwent the procedures in a screening setting. The results are expressed in two ways: individual polyp detection (per-polyp) and patient detection (per-patient). Table 2 reports the per-polyp sensitivity, classified according to the size of each polyp detected with CTC and OC, from the studies included in this review. In particular, information on sensitivity was collected for both CTC and OC from each study, using the following thresholds: ≤5, 6–9 mm, and ≥10 mm. The overall sensitivity is also reported. Table 3 shows the overall per-patient sensitivity, specificity, positive predictive value, and negative predictive value of CTC and OC for the detection of colorectal lesions.

Fig. 1.

Study selection flowchart according to preferred reporting items for systematic reviews and meta-analyses (PRISMA). CT, computed tomography; CTC, computed tomography colonography; OC, optical colonoscopy.

Characteristics of the Included Studies

Per-polyp (%) Sensitivity of Computed Tomography Colonography and Optical Colonoscopy

Per-patient (%) Sensitivity, Specificity, Positive Predictive Value, and Negative Predictive Value of Computed Tomography Colonography and Optical Colonoscopy

DISCUSSION

Colonoscopy and CTC are both highly accurate structural examinations that allow the inspection of the whole colon and are valid options for CRC screening. In particular, colonoscopy is considered the reference standard for the detection of colorectal polyps or CRC, despite being an invasive procedure associated with complications such as bleeding and perforation. Although OC is an accurate examination, it may miss 10–20% of colorectal polyps and 5% of colorectal tumors [31,32]. Furthermore, 10–15% of colonoscopies (22–33% in older patients) [9] fail to be completed even if performed by experienced endoscopists, for several reasons (e.g., in cases of an abnormal colonic shape or length or in the presence of obstructing colonic tumors or stenosis); thus, in these cases, CTC is performed to evaluate the nonvisualized parts of the colon [33]. Maggialetti et al. [9] evaluated the role of CTC in patients who had previously undergone an incomplete OC and found that CTC allowed the complete evaluation of the nonvisualized parts of the colon in these patients, increasing the diagnostic yield of lesions in that part of the colon and allowing the assessment of extracolonic findings. In fact, one of the main advantages of CTC is that extracolonic findings can be simultaneously obtained, although they are prognostically relevant in only a few cases (2–5%). CTC also offers the advantage of identifying the precise segmental location of colorectal tumors, which is not always possible with colonoscopy because of the difficulty in identifying anatomical landmarks. Correct preoperative localization of CRC is important in determining the adequate treatment during surgical planning, especially for laparoscopic procedures. Furthermore, CTC guarantees accurate tumor staging [14].

Offermans et al. [34] compared CTC and OC in terms of localization of colorectal lesions, using the surgical location to determine the segmental localization. They found that the error rate of CTC in segmental localization was lower than that of OC, especially when the neoplasms are located in the descending colon and cecum. CTC also has an established role in the preoperative evaluation of patients with occlusive CRC, allowing the visualization of the proximal colon. Several studies have reported that when an occlusive CRC is detected, 1.5–9% of patients have a synchronous cancer and 27–55% have coexisting polyps [15]. However, few studies have focused on the accuracy of CTC in diagnosing synchronous colonic lesions. In a recent study, Flor et al. [35] showed that the per-patient sensitivity and specificity of CTC in detecting synchronous lesions ≥6 mm were 93% and 98%, respectively; those in detecting synchronous adenomatous lesions were 89% and 100%, respectively; and those in detecting synchronous CRC were 94% and 100%, respectively. They concluded that CTC is a highly accurate procedure for detecting synchronous colonic lesions in patients with occlusive CRC. The detection of synchronous lesions is crucial for establishing the correct surgical management plan and avoiding subsequent reoperation. In addition, CTC has received considerable attention since its introduction in 1994, but has emerged only in recent years as a potential screening examination with high accuracy for the detection of colorectal lesions and a comparable diagnostic yield to colonoscopy for colorectal neoplasia but with a lower risk of complications [36]. The sensitivity and specificity of CTC have improved during the past few years, owing to important advances in CT technology, especially in terms of imaging in multiple sections. In fact, single-section CTC has a low sensitivity for the detection of lesions <10 mm and flat lesions and a high false-positive rate because of its inability to differentiate fecal material from polyps. The use of multidetector-row CT scanners that allow thinner section collimation has improved polyp detection through better bowel distension and fewer respiratory artifacts, due to faster data acquisition, and has decreased the false-positive rate [16]. Another important concern is radiation exposure during CTC, which may lead to increased radiation-related risks of cancer and death. The radiation dose can be decreased by using low-dose protocols and new dose modulation techniques, by increasing the section collimation and pitch, and by decreasing the kilovolt or milliampere-second values [16,17]. Macari et al. [16] and Iannaccone et al. [18] reported that lower-dose multidetector-row CTC ensured substantial dose reduction while maintaining good sensitivity and specificity for the detection of colorectal lesions >6 mm and excellent sensitivity and specificity for lesions >10 mm. One of the first studies to compare CTC and OC for the detection of colorectal lesions was conducted by Fenlon et al. [19], who found that CTC and OC had a similar ability in detecting lesions >6 mm, although they admitted that the diagnostic accuracy in their study may have been overestimated because they included only high-risk patients. Yee et al. [20] conducted the first large study on CTC as a screening test for colorectal lesions in asymptomatic average-risk patients and symptomatic high-risk patients. They found that the performance of CTC was comparable between the two groups. On the basis of their results, the authors affirmed that CTC is a valid screening examination in patients with a low risk of CRC. Meanwhile, Van Gelder et al. [37] reported that CTC and OC had similar ability in identifying colorectal lesions in patients with a high risk of CRC. Furthermore, Kim et al. [36] and Pickhardt et al. [21] reported that CTC is comparable to OC in terms of the detection of clinically relevant lesions. They recommended CTC as the preferred screening strategy because it seems to achieve the same goals as colonoscopy (prevention and detection) but uses fewer resources and has a lower rate of complications. Graser et al. [17] showed that high-resolution, low-dose CTC was comparable to OC in terms of sensitivity and may be considered an alternative screening test to colonoscopy. However, they also compared CTC and OC with sigmoidoscopy and FOBT. They concluded that for patients who refused full bowel preparation or either CTC or OC, sigmoidoscopy should be preferred over stool tests and fecal immunochemical tests should be preferred over FOBT. Therefore, on the basis of data reported in the literature, CTC and OC have a similar diagnostic accuracy and have no important differences in the detection of colorectal lesions in symptomatic high-risk patients. However, it must be emphasized that the performance of CTC is highly dependent on the size of the lesions and CTC has shown poor performance in detecting individual lesions <5 mm, although the prevalence of malignancy in diminutive polyps is extremely small (approximately 0.25%) and the probability of degeneration is very low [22]. Ginnerup et al. [23] reported that CTC and OC have similar overall detection rates for colorectal lesions >6 mm. Devir et al. [24] and Gluecker et al. [25] showed that CTC has good sensitivity and specificity for the detection of colorectal lesions >10 mm, although its accuracy in detecting polyps decreased as the size of the lesions decreased. These results are similar to those reported by Pineau et al. [22], Laghi et al. [15], and Hoppe et al. [26]. Additionally, Chaparro Sánchez et al. [27] found that the sensitivity of CTC for the detection of colorectal lesions was highly variable and dependent on the lesion size: sensitivity was greater for larger lesions and considerably lower for lesions <5 mm. Flat lesions are difficult to detect with CTC because the conspicuity of flat lesions on three-dimensional endoluminal imaging is diminished, frequently resulting in false-negative findings [14]. Flat polyps are more likely to be missed than sessile or pedunculated polyps, as flat polyps do not or only slightly alter the colonic contour. In several studies, flat lesions detected with conventional colonoscopy were missed with CTC; thus, flat lesions remain a diagnostic challenge for CTC [15,25]. However, the detection of these lesions is important because 15–30% of CRCs originate from serrated polyps rather than from adenomatous polyps; therefore, preventive strategies must target not only adenomas but also all premalignant conditions [38]. Ijspeert et al. [39] conducted the first study that compared the detection rate of high-risk sessile serrated polyps (SSPs) between CTC and OC. They showed that flat SSPs with dysplasia located in the proximal colon were often not detected with CTC, probably because of the tendency of SSPs to flatten during the distension of the colon, called the “disappearing phenomenon”, especially if they are flat and located in the cecum or in the ascending colon. However, not all literature data confirm the similarity of CTC and OC in terms of diagnostic accuracy, sensitivity, and specificity for the detection of colorectal lesions, and there are controversial results across different studies. Johnson et al. [28] reported a lower sensitivity of CTC in the detection of colorectal lesions than that reported in previous studies, which was probably because previous studies were based on cohorts with a high lesion prevalence. In addition, Spinzi et al. [29] reported that CTC had poor sensitivity in detecting colorectal polyps and did not always detect neoplastic lesions or flat lesions. Cotton et al. [30] concluded that the diagnostic accuracy of CTC is significantly inferior to that of OC and that CTC needs to be improved for widespread clinical application. However, data reported in the literature might have been influenced by various factors, and the discrepancies among various studies may be attributable to differences in bowel preparation, endoscopist and radiologist experience, scanning techniques, endoscopic measurement of lesions, and segmental localization. In terms of the preference of patients for CTC or OC, the literature reports heterogeneous data. Most patients may prefer CTC for CRC screening for reasons such as greater tolerability, less invasiveness, less fear of the procedure, reduced lower air insufflation, and lower risk of complications [40]. Nevertheless, the use of premedication in OC has drastically changed the opinion of patients because it allows them to avoid experiencing pain, discomfort, and embarrassment by sleeping through the procedure [41].

CONCLUSIONS

Colonoscopy is widely accepted as the gold standard for the detection of colorectal polyps and CRC and has the advantage of being both diagnostic and therapeutic; however, CTC is a better modality than OC for the visualization of the whole colon, detection of synchronous lesions, and accurate localization of tumors. The diagnostic accuracy of CTC has increased over time owing to improvements in scanning techniques, making it a valuable clinical screening method for colorectal neoplasms. It is widely accepted that the accuracy of CTC is comparable to that of colonoscopy for polyps >10 mm, acceptable but not equal to that of colonoscopy for lesions between 5 and 9 mm, and poor for lesions <5 mm.

Notes

Conflicts of Interest: The authors have no potential conflicts of interest.

Funding

None.

Author Contributions

Conceptualization: Alessia Chini, Michele Manigrasso

Data curation: Marco Milone

Formal analysis: Francesco Maione

Investigation: Grazia Cantore

Methodology: MMi

Project administration: AC

Resources: Rosa Maione

Supervision: Giovanni Domenico De Palma

Validation: AC, FM, GDDP

Visualization: FM

Writing-original draft: MMa

Writing-review & editing: AC

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Article information Continued

Fig. 1.

Study selection flowchart according to preferred reporting items for systematic reviews and meta-analyses (PRISMA). CT, computed tomography; CTC, computed tomography colonography; OC, optical colonoscopy.

Table 1.

Characteristics of the Included Studies

Study Type of study No. of patients Mean age, years (range) Screening setting
Munikrishnan et al. (2003) [13] Single-center, prospective 80 68 (29–83) No
Singh et al. (2015) [14] Single-center, prospective 50 - No
Laghi et al. (2002) [15] Single-center, prospective 66 61 (30–84) No
Macari et al. (2002) [16] Single-center, prospective 105 58 (49–79) No
Graser et al. (2009) [17] Single-center, prospective 311 60.5 (50–81) Yes
Iannaccone et al. (2003) [18] Single-center, prospective 158 64 (50–80) No
Fenlon et al. (1999) [19] Single-center, prospective 100 62 (50–77) No
Yee et al. (2001) [20] Single-center, prospective 300 62.6 (25–90) No
Pickhardt et al. (2003) [21] Multicenter, prospective 1253 57.8 (40–79) Yes
Pineau et al. (2003) [22] Single-center, prospective 206 59.3 (38–83) No
Ginnerup Pedersen et al. (2003) [23] Single-center, prospective 148 60 (25–86) No
Devir et al. (2016) [24] Single-center, prospective 31 45 (38–74) Yes
Gluecker et al. (2002) [25] Single-center, prospective 51 60 (50–75) No
Hoppe et al. (2004) [26] Single-center, prospective 100 66 (20–91) No
Chaparro Sánchez et al. (2007) [27] Single-center, prospective 50 62 (25–83) No
Johnson et al. (2003) [28] Single-center, prospective 703 64 (50–84) No
Spinzi et al. (2001) [29] Single-center, prospective 99 - No
Cotton et al. (2004) [30] Multicenter, prospective 615 61 No

Table 2.

Per-polyp (%) Sensitivity of Computed Tomography Colonography and Optical Colonoscopy

Study CTC
OC
Overall ≤5 mm 6–9 mm ≥10 mm Overall ≤5 mm 6–9 mm ≥10 mm
Munikrishnan et al. (2003) [13] 76 53 83 100 - - - -
Singh et al. (2015) [14] 97.5 - - - 92.68 - - -
Laghi et al. (2002) [15] 57.6 24 84.6 92.8 - - - -
Macari et al. (2002) [16] 21 12 53 100 - - - -
Graser et al. (2009) [17] 70.1 59.2 90.2 93.9 95.9 94.6 92.7 100
Iannaccone et al. (2003) [18] 70 51 83 100 - - - -
Fenlon et al. (1999) [19] 71 55 82 91 - - - -
Yee et al. (2001) [20] 69.7 59.1 80.1 90 - - - -
Pickhardt et al. (2003) [21] 91.5 85.7 92.6 92.2 88.1 90 89.5 88.2
Pineau et al. (2003) [22] 63.6 29.4 75 87.5 - - - -
Ginnerup Pedersen et al. (2003) [23] 81 - 71 83 87 - 100 70
Devir et al. (2016) [24] 83.3 87.5 75 91.7 - - - -
Gluecker et al. (2002) [25] 22 4 33 82 - - - -
Hoppe et al. (2004) [26] 43 25 50 71 94 - - -
Chaparro Sánchez et al. (2007) [27] - 15 75 75 - - - -
Johnson et al. (2003) [28] 57.8 - 54 63 - - - -
Spinzi et al. (2001) [29] 58 56 - 62 - - - -
Cotton et al. (2004) [30] 39 7.6 22.7 52 98 97 99 96

CTC, computed tomography colonography; OC, optical colonoscopy.

Table 3.

Per-patient (%) Sensitivity, Specificity, Positive Predictive Value, and Negative Predictive Value of Computed Tomography Colonography and Optical Colonoscopy

Study CTC
OC
Sensitivity Specificity PPV NPV Sensitivity Specificity PPV NPV
Munikrishnan et al. (2003) [13] 97 98 96 98 - - - -
Singh et al. (2015) [14] 97.56 100 100 93.75 92.68 100 100 83.3
Laghi et al. (2002) [15] 93.7 94.1 - - - - - -
Macari et al. (2002) [16] 32.5 97.7 93 85.3 - - - -
Graser et al. (2009) [17] 84.1 47.4 48.2 83.6 97.3 59.8 58.5 97.5
Iannaccone et al. (2003) [18] 96 96.6 94.1 97.7 - - - -
Fenlon et al. (1999) [19] 82 84 82 84 - - - -
Yee et al. (2001) [20] 90.1 72 83.3 82.5 - - - -
Pickhardt et al. (2003) [21] 88.7 79.6 - - 92.3 - - -
Pineau et al. (2003) [22] 61.8 70.7 61.8 70.7 - - - -
Ginnerup Pedersen et al. (2003) [23] 91 97 - - - - - -
Devir et al. (2016) [24] 83 95 95 83 - - - -
Gluecker et al. (2002) [25] - - - - - - - -
Hoppe et al. (2004) [26] 73 88 79 86 - - - -
Chaparro Sánchez et al. (2007) [27] 75 89 - - - - - -
Johnson et al. (2003) [28] - - - - - - - -
Spinzi et al. (2001) [29] 57.8 92.6 86.7 - - - - -
Cotton et al. (2004) [30] 39 90.5 - - 99 100 - -

CTC, computed tomography colonography; NPV, negative predictive value; OC, optical colonoscopy; PPV, positive predictive value.