Abstract
Current concepts in CT colonography will be highlighted, including discussions on proper technique, data related to patient acceptance, safety, the prevalence of extracolonic findings and their significance, and the practitioners’ responsibility for maintaining high-quality outcomes.
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Keywords
FormalPara Learning Objectives-
To implement proper technique for obtaining a high-quality CT colonography examination
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To educate others regarding the safety and performance of CT colonography
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To participate in a quality improvement program related to CT colonography
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To recognize difficult-to-detect lesions at CT colonography
The public health need for colorectal cancer screening is compelling. Colorectal cancer is common, accounting for approximately 50,000 deaths yearly in the USA [1]. The benign precursor adenoma can be detected by several different imaging techniques, and, if removed, can prevent malignant transformation. The approximately 10-year polyp dwell time allows ample opportunity for patients to be screened and polyps detected and removed. Potentially, under ideal screening circumstances, an entire class of cancers could be prevented. Unfortunately, barriers exist to ideal screening, including suboptimal performance of many existing colorectal screening tests, reluctant compliance by patients to follow recommended screening guidelines, and variable insurance coverage of examination charges. In many ways, CT colonography (CTC) approaches an ideal screening test by addressing issues and problems inherent with other techniques. This syllabus will highlight many key issues for CT colonography today.
16.1 Technique
Proper technique at CT colonography is imperative for high performance. The three main steps include preparation, CT scanning, and interpretation.
16.1.1 Preparation
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1.
Dietary restriction. Preparation begins with a recommendation for patients to consume clear liquids or a low-residue diet for at least 1 day prior to beginning the cathartic bowel preparation. Although this step is optimal, it can be skipped if patients are following the subsequent instructions carefully.
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Stool tagging. 10–20 mL of barium or iodinated contrast material is administered orally for three meals prior to beginning the cathartic preparation. This contrast agent mixes with stool and ideally is evacuated with the cathartic preparation. Residual stool will contain high-attenuation contrast and can be easily discriminated from soft tissue attenuation polyps. Some prefer to perform stool tagging after the cathartic agent, but before fluid tagging.
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Cathartic. The cathartic preparation can be performed with a number of different formulations including polyethylene glycol electrolyte solution and magnesium citrate or bisacodyl tablets. Phospho-soda agents are not recommended because of prior issues with renal insufficiency and sodium retention. Bisacodyl tablets require the patient to be well hydrated for the purgation process to be successful. Bisacodyl tablets are easy to consume and well tolerated by patients. Polyethylene glycol electrolyte solution provides the cleanest colon, but some patients find it more difficult to consume in its entirety.
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Fluid tagging. Following the cathartic preparation, the small bowel will continue to secrete soft tissue attenuation fluid into the colon. This fluid can obscure immersed polyps. Tagging of this fluid is accomplished by drinking 60 ml of iodinated contrast material (either hyperosmolar or iso-osmolar) at bedtime, on the day before the exam. The high attenuation tagging allows inspection of the immersed portions of the colon wall and visualization of any colon lesions within this fluid.
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Insufflation. The colon must be fully distended with air or carbon dioxide for optimal visualization at CT. Commercially available insufflation devices are available instilling C02 at a predefined rate and pressure. Excess intraluminal colonic pressure during a colonic contraction will result in venting of gas into the room—thereby reducing patient discomfort and the risk of perforation. As the pressure is reduced, the machine automatically refills the colon. Turning the patient on the CT table is helpful in creating a well-distended colon.
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Spasmolytics [2]. The use of spasmolytics is controversial. Although it has not been shown to improve image quality, there are some that believe the exam is more comfortable for patients [3].
16.1.2 CT Scanning
Acquisition of CT data using thin collimation and isotropic reconstruction intervals will result in high-quality images in any desired plane. The colon and rectum data should be acquired in a single breath-hold, using a low-dose technique. Generally, we use a 1 mm collimation, reconstructing every 0.8 mm, 50 mAs. Optimally, new reconstruction software should be employed to enable ultralow-dose acquisition. Ideally, average patients should receive an effective dose equivalent of less than 5 mSv [4].
16.1.3 Interpretation
There are two main ways to interpret a CTC examination: either a primary 2D with 3D problem-solving or primary 3D with 2D problem-solving approaches. Both methods have been shown to have equal effectiveness. Most authorities advocate that each exam should have both a 2D and 3D review. Small polyps are more easily detected with a 3D (endoluminal) review, whereas obstructing cancers and flat lesions are better detected with a 2D review. There is no proven difference between software manufacturers in lesion detection [5] (Fig. 16.1).
16.2 Performance
The performance of CT colonography has undergone exhaustive testing. The Department of Defense (DoD) trial by Pickhardt et al. demonstrated sensitivity similar to colonoscopy [6], but concerns were raised that community practices might not be able to achieve these results. The National CT Colonography Trial findings were similar to the Pickhardt’s trial and have reassured many groups [7] that the test can be performed with high accuracy in both academic and private practice settings.
Training and preferably testing of radiologists are requirements for optimal reader performance [8]. Participation in a dedicated training program is recommended. These training sessions should provide enough time for the radiologist to become facile with a specific colonography software package and experience interpreting at least 50 proven cases. Polyp detection testing will allow individuals an opportunity to assess if additional training is needed before clinical implementation. In order to continue to improve reader performance, it is recommended that patients who are undergoing both CTC and subsequent colonoscopy be reviewed retrospectively to assess for CTC false-positive and false-negative detections. This quality improvement review offers a rich experience for learning and gaining expertise, confidence, and competence. Strict adherence to state-of-the art CTC protocol requirements is also recommended including stool and fluid tagging regimens, mechanical insufflation of the colon, thin-section data acquisition, and low-dose CT techniques [9]. It is clear that meticulous attention to all aspects of the examination and interpretation is required to achieve the best results.
16.3 Acceptance
Today, nearly 40 million US adults age 50 or older have not undergone a sigmoidoscopy or colonoscopy within the previous 10 years or had used a fecal occult blood test (FOBT) home test kit within the preceding year [10]. The major disincentive for patients undergoing a full structural colorectal examination is the laxative purgation [11]. Work is being done to reduce the burden of laxation either with the use of a partial colon preparation [12] or without cathartic preparation [13]. Although not considered standard of care, evidence from feasibility trials is promising and may translate to better patient acceptance in the future.
Despite a full cathartic bowel preparation, the advantages of CTC include the lack of required sedation and intravenous line placement, a quick return to work following the examination, and the convenience of no driving restrictions following the test.
The disadvantage of CTC includes the fact that if a significant polyp is identified, patients must undergo colonoscopy and polypectomy. If same-day colonoscopy is not offered, then the patient must undergo a second bowel preparation, spend another day away from work, and experience added worry and inconvenience. In a screening population (including false-positive interpretations), the prevalence of patients being referred from CTC to colonoscopy for polypectomy is 12% when a 6 mm threshold is applied [6, 7]. This translates into an 88% chance that an individual patient will not require a second procedure—thereby mitigating concerns for redundancy. Those with a high likelihood of polyps may best be triaged to colonoscopy screening.
16.4 Safety
The main risk for patients at CTC is the risk of colorectal perforation. The symptomatic perforation rate has been estimated to be 1:20,000 examinations and likely safer among screening patients [14]. In contrast, colonoscopy perforation rates have been recorded to be in the range of 1:1000 [15], often but not always related to biopsy procedures. Bleeding can also follow colonoscopy intervention and is more common than perforation.
Radiation risk from a CTC examination has been of public concern. It is unfortunate that the risk associated with the low radiation dose required for CTC has been misunderstood. The standard dose at CTC represents about 25–50% of the dose used for a standard body CT examination. This results in an average dose of approximately 2.5–5 mSv, similar to annual environmental exposures in many locales that is without known adverse health effects. The doses at CTC can be reduced significantly even further using new noise reduction software (iterative reconstruction). The real risk of this small dose is unknown, but the Health Physics Society has stated that doses in this range are associated with risks for the development of radiation-induced cancer that are either too small to measure or are nonexistent [16]. Even if a very small risk is assumed from radiation exposure at CT, it must be balanced against the risk of developing colon cancer (1:13) and the risks of other alternative procedures including colonoscopy [17].
16.5 Extracolonic Findings
Extracolonic abnormalities are common in patients of screening age [18, 19]. Although lifesaving findings can be identified, most incidental findings are of little clinical significance but can potentially increase the cost of care if additional testing and treatment are recommended. A pragmatic approach to these findings is needed. Radiologists should only recommend follow-up studies for those findings most likely to be of clinical significance. Clinicians will be grateful if additional testing is minimized and for those that might benefit from additional studies to include recommendations for optimal follow-up within the radiologic report.
16.6 Individual Responsibility
Maintaining high-quality interpretations is a responsibility that each individual, each practice, and our specialty should assume. The ACR has established a national CTC database within the National Radiology Data Registry (NRDR) [20]. Selected process and outcome metrics can be quickly entered online and compared to national benchmarks. These measures include process metrics related to the CT technique and the adequacy of patient preparation, outcome metrics related to colon perforation, true positive and false-positive rates for large (≥1 cm) polyps, and the prevalence of significant extracolonic findings. Practices seriously interested in providing the best care should be encouraged to participate in this data registry and manage their practice so benchmark metrics are achieved.
A spirit of cooperation between radiologists and gastroenterologists is needed for optimal patient care. Guidelines will need to be jointly developed for the proper use of colonography and colonoscopy and for processes to efficiently transfer patients with polyps to colonoscopy. Those practices that are able to do this effectively will offer patients a service of high value and will likely find themselves very busy.
Key Point
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CT colonography is a well-validated examination and should be available clinically. Radiologists committed to performing the examination to the highest quality must obtain the education and equipment needed. We have an obligation to educate and to collaborate with referring physicians on the correct use of the technique. We must be vigilant that extracolonic findings are properly reported so that only highly suspicious lesions have recommended additional follow-up testing. Lastly, a commitment to incorporate ongoing quality measures within your daily practice will ensure that patients continue to receive the highest standards of care. Radiology has an exciting opportunity to serve the public and potentially reduces the incidence of a common cancer killer.
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Johnson, C.D., Pickhardt, P.J. (2018). Diseases of the Colon and Rectum: CT Colonography. In: Hodler, J., Kubik-Huch, R., von Schulthess, G. (eds) Diseases of the Abdomen and Pelvis 2018-2021. IDKD Springer Series. Springer, Cham. https://doi.org/10.1007/978-3-319-75019-4_16
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