Colorectal Cancer Screening: Recommendations for Physicians and Patients from the U.S. Multi-Society Task Force on Colorectal Cancer : Official journal of the American College of Gastroenterology | ACG

Secondary Logo

Journal Logo


Colorectal Cancer Screening: Recommendations for Physicians and Patients from the U.S. Multi-Society Task Force on Colorectal Cancer

Rex, Douglas K MD1; Boland, Richard C MD2; Dominitz, Jason A MD, MHS3; Giardiello, Francis M MD4; Johnson, David A MD5; Kaltenbach, Tonya MD6; Levin, Theodore R MD7; Lieberman, David MD8; Robertson, Douglas J MD, MPH9

Author Information
American Journal of Gastroenterology 112(7):p 1016-1030, July 2017. | DOI: 10.1038/ajg.2017.174
  • Free



This document updates the colorectal cancer (CRC) screening recommendations of the U.S. Multi-Society Task Force of Colorectal Cancer (MSTF), which represents the American College of Gastroenterology, the American Gastroenterological Association, and The American Society for Gastrointestinal Endoscopy. CRC screening tests are ranked in 3 tiers based on performance features, costs, and practical considerations. The first-tier tests are colonoscopy every 10 years and annual fecal immunochemical test (FIT). Colonoscopy and FIT are recommended as the cornerstones of screening regardless of how screening is offered. Thus, in a sequential approach based on colonoscopy offered first, FIT should be offered to patients who decline colonoscopy. Colonoscopy and FIT are recommended as tests of choice when multiple options are presented as alternatives. A risk-stratified approach is also appropriate, with FIT screening in populations with an estimated low prevalence of advanced neoplasia and colonoscopy screening in high prevalence populations. The second-tier tests include CT colonography every 5 years, the FIT-fecal DNA test every 3 years, and flexible sigmoidoscopy every 5 to 10 years. These tests are appropriate screening tests, but each has disadvantages relative to the tier 1 tests. Because of limited evidence and current obstacles to use, capsule colonoscopy every 5 years is a third-tier test. We suggest that the Septin9 serum assay (Epigenomics, Seattle, Wash) not be used for screening. Screening should begin at age 50 years in average-risk persons, except in African Americans in whom limited evidence supports screening at 45 years. CRC incidence is rising in persons under age 50, and thorough diagnostic evaluation of young persons with suspected colorectal bleeding is recommended. Discontinuation of screening should be considered when persons up to date with screening, who have prior negative screening (particularly colonoscopy), reach age 75 or have <10 years of life expectancy. Persons without prior screening should be considered for screening up to age 85, depending on age and comorbidities. Persons with a family history of CRC or a documented advanced adenoma in a first-degree relative age <60 years or 2 first-degree relatives with these findings at any age are recommended to undergo screening by colonoscopy every 5 years, beginning 10 years before the age at diagnosis of the youngest affected relative or age 40, whichever is earlier. Persons with a single first-degree relative diagnosed at ≥60 years with CRC or an advanced adenoma can be offered average-risk screening options beginning at age 40 years.

Colorectal cancer (CRC) screening is the process of detecting early-stage CRCs and precancerous lesions in asymptomatic people with no prior history of cancer or precancerous lesions. The U.S. Multi-Society Task Force of Colorectal Cancer (MSTF) is a panel of expert gastroenterologists representing the American College of Gastroenterology, the American Gastroenterological Association, and the American Society for Gastrointestinal Endoscopy. The MSTF, like others, has long endorsed systematic offers of CRC screening to average-risk persons (persons without a high-risk family history of colorectal neoplasia) beginning at age 50 years, with general evidence supporting screening reviewed in previous publications (1). This publication updates the screening recommendations of the MSTF for screening in average-risk persons (1).

Screening differs from surveillance. Surveillance refers to the interval use of colonoscopy in patients with previously detected CRC or precancerous lesions and interval colonoscopy in patients performed to detect dysplasia in persons with inflammatory bowel disease affecting the colon. Surveillance recommendations from the MSTF on surveillance after cancer (2) and removal of precancerous lesions (3) are available in other documents. Screening is also distinct from diagnostic examinations, which refer to the investigation of patients with symptoms or positive screening tests other than colonoscopy. Colonoscopy is generally the test of choice for diagnostic examinations.


Literature review

The English language medical literature using MEDLINE (2005 to August 1, 2016), EMBASE (2005 to third quarter 2016 update), the Database of Abstracts of Reviews and Effects (2005 to third quarter 2016 update), and the Cochrane Database of Systematic Reviews (2005 to third quarter 2014 update) was searched. In MEDLINE, subject headings for colorectal cancer screening were combined with headings for fecal occult blood test, fecal immunochemical test, colonoscopy, sigmoidoscopy, CT colonoscopy, fecal DNA, serum testing, cost-effectiveness, and quality. Similar searches were performed in EMBASE, the Database of Abstracts of Reviews and Effects, and the Cochrane Database of Systematic Reviews. Case reports and studies performed in patients with inflammatory bowel disease, prior CRC or polyps, or hereditary CRC syndromes were excluded. Review papers, meta-analyses, gastroenterology textbooks, and editorials were searched manually for additional pertinent references. The review includes studies published since 2008 but also incorporates older evidence used to draft the 2008 recommendations (1). Evidence-based weighted recommendations are provided with supporting discussion to help guide clinicians in the management of these patients.

Process and levels of evidence

Guidance statements were developed by consensus obtained through joint teleconferences. The completed article was reviewed and approved by all 3 gastroenterology societies.

The use of GRADE for MSTF guidance papers has been outlined in detail elsewhere (2). GRADE involves comprehensive literature search and summary (often through meta-analysis) and then a separate review of literature quality and development of recommendations. The MSTF uses a modified qualitative approach based on literature review (as described above for this article) but without formal meta-analysis. GRADE allows for a separate assessment of the quality of the evidence and strength of recommendation. This approach explicitly recognizes the importance of literature in informing clinical recommendations but allows latitude because recommendations may be influenced by other factors, such as patient preference, cost, and expert consensus. “Strong recommendations” are those that would be chosen by most informed patients. “Weak recommendations” are those where patient values and preferences might play a larger role than the quality of evidence. Within the document we preface strong recommendations with phrases such as “we recommend” and weak recommendations with “we suggest.”

Approaches to screening

In the United States CRC screening usually results from an office-based interaction between a healthcare provider and patient. Screening in this setting is termed opportunistic (4).

Programmatic screening (sometimes called organized screening) refers to a system-wide, organized approach to offering screening to a population or members of a healthcare plan (4). Programmatic screening has potential advantages over opportunistic screening, including systematic offers of screening, reduction of overscreening, superior monitoring of quality, and systematic follow-up of testing. National CRC screening programs in Europe (5) and Australia (6) use fecal occult blood testing and include screening colonoscopy in Germany and Poland (5). The United States has no national program for CRC screening, although several large healthcare plans offer programmatic screening, typically with a fecal immunochemical test (FIT) (7). Despite the potential advantages of programmatic screening, the United States has achieved the world's highest rates of CRC screening compliance at 60% and the greatest CRC incidence and mortality reduction, using an almost entirely opportunistic approach (8, 9, 10, 11, 12). Incidence reductions in the United States were 3 to 4% per year and 30% overall in the first decade of this century (11, 12). High rates of screening in the United States may reflect widespread awareness of CRC and insurance coverage of screening. The MSTF anticipates growth of programmatic screening within healthcare systems but expects at least short-term continued reliance on opportunistic screening in the United States. Reliance on opportunistic screening can affect the preference for CRC screening, because achieving compliance with tests that should be repeated at short intervals is more challenging in the opportunistic setting (13).

In the setting of opportunistic screening, healthcare providers can use several broad strategies to offer screening to patients. One approach is multiple options, in which the benefits, risks, and costs of 2 or more tests are discussed and offered to patients (Table 1) (14). Some evidence suggests that when patients are offered both colonoscopy and fecal occult blood testing, more patients undergo screening (15). Other data suggest no benefit in overall compliance when multiple options are offered (16, 17, 18). In 1 study, offering patients 5 options did not enhance compliance over 2 options (19). In this regard, at least 9 different screening tests (colonoscopy, FIT, guaiac-based fecal occult blood test, FIT-fecal DNA, sigmoidoscopy, sigmoidoscopy plus fecal occult blood test, CT colonography, barium enema, and the Septin9 serum assay [Epigenomics, Seattle, Wash]) are endorsed or discussed in recent major screening guidelines (14, 20). Thus, the multiple options discussion may best be limited to 2 or 3 preferred options. If patients decline all the offered options, 1 or more of the other options can be offered.

Table 1:
Approaches to offering screening in the opportunistic setting

The sequential approach to screening involves an offer of a first test that is usually the provider's preferred screening option; if the patient declines the first option, a second test is offered, and so on. In the United States the sequential approach often involves an offer of colonoscopy, followed by FIT if colonoscopy is declined, or another screening test (9). Separate guidelines from the American College of Gastroenterology (21) and the American Society for Gastrointestinal Endoscopy (22) recommend a sequential approach with colonoscopy offered first. Sequential testing can maximize compliance overall as well as with the test recommended first (23, 24, 25). Clinicians using the colonoscopy-first sequential approach place emphasis on the high efficacy of colonoscopy in preventing CRC and less emphasis on the risks of colonoscopy. Indeed, high-quality colonoscopy has both higher single-time testing efficacy and greater risks than any other screening tests but with absolute risk rates that are still very low when performed by skilled operators (26). A variant of sequential testing often used in the programmatic setting is to offer patients FIT as the initial or preferred test and have other options such as colonoscopy available to patients who express interest in alternatives (4).

A third approach to offering screening to average-risk persons is a risk-stratified approach. Risk stratification uses evidence that the “average-risk” population actually represents a wide range of risk that can be estimated based on demographic and other risk factors. For example, older age, male gender, obesity, diabetes, and cigarette smoking are all associated with colorectal adenomas and cancer and therefore might be used in stratifying risk within the average-risk population (21). The goal is to predict subgroups of patients with a high prevalence of important precancerous lesions benefiting most from referral directly to colonoscopy, whereas the subgroups with a predicted lower risk (prevalence) of important precancerous lesions are referred for screening tests with less risk and cost than colonoscopy. Risk stratification has been poorly accepted because of limited accuracy in discriminating high- and low-prevalence subgroups (27). However, recent validated models appear to be simple to apply and had substantial accuracy in defining high- and low-risk groups for advanced adenomas (28, 29). There are no clinical trials comparing compliance or other outcomes using a risk-stratified approach to the multiple options or sequential approaches. Few data are currently available regarding ease of application of a risk-stratified approach in clinical practice.

The MSTF considers that each of the approaches outlined above is reasonable when offering screening in the opportunistic setting. There is insufficient evidence to identify one approach as superior. Patients undergoing screening tests other than colonoscopy should understand that colonoscopy is used to evaluate these tests when positive. In some instances insurance coverage of colonoscopy performed to evaluate other positive screening tests may be less than coverage of primary screening colonoscopy. Awareness of the different approaches may assist clinicians in understanding screening literature and in selecting an approach to offering screening that seems to be optimal for their practice or for an individual patient.


  1. We recommend that clinicians offer CRC screening beginning at age 50 (strong recommendation, high-quality evidence). (See below for adjustments in recommended age for onset of screening based on race and family history.)
  2. We suggest that sequential offers of screening tests, offering multiple screening options, and risk-stratified screening are all reasonable approaches to offering screening (weak recommendation, low-quality evidence).

Screening targets

The object of screening is to reduce CRC incidence and mortality. To accomplish both aims, tests need to detect early-stage (i.e., curable) CRCs and high-risk precancerous lesions (1, 21). Detection and removal of precancerous lesions prevents CRC (30, 31). The 2 main classes of precancerous lesions in the colon are conventional adenomas and serrated class lesions (Table 2). These 2 classes of precancerous lesions have distinct endoscopic features and histology and different (though overlapping) distributions within the colorectum. Specific screening tests sometimes have particular strengths or weaknesses detecting 1 or the other class of precancerous lesions, particularly the serrated class. Therefore, we review here the main clinical features of the 2 classes of precancerous lesions.

Table 2:
Histologic classification of the two major classes of colorectal polyps

Adenomas, also known as conventional adenomas, are the precursors of perhaps 70% of all CRCs (32, 33). The adenoma-carcinoma sequence is believed to typically take more than 10 years to complete in sporadic cancers, whereas much shorter intervals occur in Lynch syndrome (34). Correspondingly, colonoscopy is recommended at 10-year intervals in average-risk persons and at 1- to 2-year intervals in those with Lynch syndrome (1, 34). The distribution of adenomas is relatively even throughout the colon, although adenomas with a flat or depressed morphology are distributed more to the proximal colon and pedunculated lesions more to the distal colon (35). Adenomas are by definition dysplastic, with the overwhelming majority being low grade. The presence of high-grade dysplasia in an adenoma should be noted by a pathologist. Adenomas can also be characterized by tubular vs. villous histology, with the overwhelming majority tubular. Lesions with >25% villous elements are termed tubulovillous and those with >75% villous elements villous. Villous elements and invasive cancer are associated with increasing size of adenomas. Invasive cancer in adenomas ≤5 mm in size is extremely rare, and the prevalence remains well below 1% in adenomas 6 to 9 mm in size (36). Recent colonoscopic studies have identified lower prevalence rates of cancer in polyps <1 cm in size compared with early studies, probably because improvements in colonoscope technology and performance have led to routine detection of an array of small, flat, low-volume adenomas (36). Interobserver agreement in differentiation of high- vs. low-grade dysplasia by pathologists and tubular vs. tubulovillous histology is poor to moderate, particularly in adenomas <1 cm in size (37). Conversely, interobserver agreement between pathologists is good to excellent in placing lesions within the conventional adenomas vs. serrated polyps and in identifying invasive cancer (38).

An important clinical concept is the “advanced” adenoma, defined as a lesion ≥1 cm in size or having high-grade dysplasia or villous elements (3). Because nonadvanced adenomas have a very low prevalence of cancer and a long adenoma-cancer sequence, screening tests can remain useful if they target cancer and advanced adenomas and not small adenomas. Further, the prevalence of nonadvanced adenomas is so high in modern colonoscopy studies that detection of such lesions by noncolonoscopic screening tests leads to unacceptably low specificity. Colonoscopy has an important benefit over other screening methods because of its ability to detect and remove both advanced and nonadvanced adenomas. Although nonadvanced adenomas have limited clinical importance and are not the target of noncolonoscopic screening methods, colonoscopists strive to identify and remove nonadvanced adenomas. Thus, resecting lesions with any precancerous potential during colonoscopy is safe, seems to be better accepted by patients in the United States, and removes them as a clinical concern.

Serrated colorectal lesions (Figure 1) represent an emerging area in the field of precancerous colorectal lesions. The serrated class of precursor lesions accounts for up to 30% of CRCs (33). Within the serrated class, hyperplastic polyps are not currently considered precancerous, whereas sessile serrated polyps (SSPs; also known as sessile serrated adenoma) and traditional serrated adenomas are considered precancerous (Table 2) (33). Hyperplastic polyps are usually small lesions and are distributed toward the distal colon (39). SSPs are common (found in 8–9% of screening colonoscopies performed by expert detectors) (40, 41) and are distributed toward the proximal colon compared with conventional adenomas. SSPs are typically flat or sessile in shape, have few or no surface blood vessels (conventional adenomas by comparison have many surface vessels), and are more difficult to detect at colonoscopy than conventional adenomas (33, 42, 43). Because of their prevalence and precancerous potential, SSPs are the major precancerous serrated lesion. There is poor interobserver agreement between pathologists in the differentiation of hyperplastic polyps from SSPs (44). Consequently, clinicians can see widely varying rates of SSPs in pathology reports, depending on the pathologist or even the center in which they practice (45). Most SSPs are not dysplastic, and the lesions should consistently be designated as “SSP without cytologic dysplasia” or “SSP with cytologic dysplasia.” (46) When a dysplastic component is present, it is often evident endoscopically (Figure 1) and histologically is a region of conventional adenoma within an otherwise serrated lesion (47). Microdissection studies indicate that the dysplastic area often has microsatellite instability (48). The SSP with cytologic dysplasia is considered a more advanced lesion in the polyp cancer sequence than SSP without cytologic dysplasia (3, 33, 49, 50).

Figure 1.:
Endoscopic photographs of conventional adenomas and sessile serrated polyps. (a) Small (8-mm diameter) conventional adenoma. The red lines are surface blood vessels. (b) A portion of a 40-mm advanced conventional adenoma; one of the targets of all screening tests. The prominent blood vessel pattern is again visible. (c) A conventional adenoma with a focus of invasive cancer. The prominent blood vessel pattern of a conventional adenoma visible over the lesion except in the ulcerated area. The cancer is located at the ulcer (arrows) (d) A sessile serrated polyp without cytologic dysplasia. Note the absence of blood vessels on the surface. (e) A sessile serrated polyp (visualized in narrow-band imaging) with multiple foci of cytologic dysplasia (yellow arrows). The dysplastic areas have the blood vessel pattern (and the histologic features) of an adenoma. The white arrows point to non-dysplastic portions of this sessile serrated polyp. (f) A sessile serrated polyp with invasive cancer; white arrows designate the residual sessile serrated polyp, whereas yellow arrows indicate the ulcerated malignant portion of the lesion.

The traditional serrated adenoma is a rare lesion, often in the left colon, sessile, and uniformly dysplastic (33, 46). Because traditional serrated adenoma is rare, dysplastic, and has a villous-like growth pattern histologically, it is often misinterpreted as a tubulovillous conventional adenoma (33).

The features of these 2 classes of precancerous lesions are relevant to the available screening tests. Colonoscopy is the criterion standard for the detection of all precancerous colorectal lesions. Colonoscopy achieves its greatest superiority relative to other screening tests in the detection of conventional adenomas <1 cm in size and serrated class lesions. Detection of SSPs is a major deficiency of flexible sigmoidoscopy because SSPs are predominantly in the proximal colon (51), of CT colonography because the lesions tend to be flat (52), and of FIT (53) probably because SSPs have no or few surface blood vessels with less tendency to bleed than conventional adenomas. The combined FIT-fecal DNA test achieves its greatest relative performance compared with FIT alone in the detection of serrated class lesions, related to the poor sensitivity of FIT for these lesions and the inclusion of hypermethylation markers in the DNA panel (53). Hypermethylation is a feature of serrated lesions (33).

Specific screening tests


The advantages of colonoscopy include high sensitivity for cancer and all classes of precancerous lesions, single-session diagnosis and treatment, and long intervals between examinations (10 years) in subjects with normal examinations. One or 2 negative examinations may signal lifetime protection against CRC (54). Patients who value the highest level of sensitivity in detection of precancerous lesions and are willing to undergo invasive screening should consider choosing colonoscopy. Although no randomized trials of colonoscopy for screening have been completed, extensive evidence from adenoma cohorts (30, 31), cohort studies on incidence and mortality (55, 56), and case-control studies (57, 58, 59, 60, 61, 62, 63, 64) support the efficacy of colonoscopy in preventing incident CRC and cancer deaths. One cohort study (56) and 3 case-control studies (58, 59, 64) were performed in screening populations. Reductions in incidence and mortality are approximately 80% in the distal colon and 40 to 60% in the proximal colon, at least in the United States and Germany (57, 59, 61, 62, 64). Furthermore, indirect evidence from randomized trials of fecal occult blood testing (65) and sigmoidoscopy (66), as well as studies showing highly variable cancer protection provided by different colonoscopists (67, 68), also supports a protective effect of colonoscopy against CRC. These findings are consistent with the observed population trends in the United States (11, 12).

Disadvantages of colonoscopy include the need for thorough bowel cleansing, a higher risk of perforation relative to the other screening tests, higher risk of aspiration pneumonitis (particularly when the procedure is performed with deep sedation) (69), a small risk of splenic injury requiring splenectomy, and a greater risk of postprocedural bleeding compared with other screening tests. A meta-analysis of population-based studies found risks of perforation, bleeding, and death of 0.5 per 1000, 2.6 per 1000, and 2.9 per 100,000, respectively (70). Bleeding after colonoscopy is almost entirely related to polypectomy. When electrocautery is used for resection of all colorectal polyps, most bleeds occur after resection of small lesions. This relates entirely to the high prevalence of these lesions because increasing polyp size and proximal colon location are the major risk factors for bleeding per individual resected polyp (71). Cold resection techniques are effective and nearly devoid of clinically significant bleeding risk and can be generally advised for nonpedunculated lesions <1 cm in size (72). Despite these risks, colonoscopy is the preferred approach to management of any benign colorectal polyp regardless of size or location because the alternative of surgical resection has higher mortality and cost compared with colonoscopy (73, 74). To the extent that other screening tests effectively identify large lesions, they result in colonoscopy and do not prevent adverse events related to colonoscopic resection of large lesions.

A major disadvantage of colonoscopy is operator dependence in performance. Operator dependence affects detection of cancer (67, 68, 75), adenomas (76, 77), and serrated lesions (40, 41, 78); selection of appropriate screening and surveillance intervals after colonoscopy (79); and effective resection of colorectal polyps (80). In general, gastroenterologists performing colonoscopy are more effective than nongastroenterologists in prevention of cancer (62, 81, 82, 83) and detection of precancerous polyps (84). However, substantial operator dependence within gastroenterologists is consistently observed (42, 43, 76, 77, 78), so that selection of a colonoscopist by specialty is not adequate protection against suboptimal operator performance. Table 3 shows a list of questions that patients can ask potential colonoscopists to judge whether performance is likely to be at a high level. Afterward, the colonoscopy report should contain the items in Table 3 as an additional check on the adequacy of the procedure.

Table 3:
Tools for patients to enhance colonoscopy quality

Fecal immunochemical test

Advantages of FIT include its noninvasive nature, 1-time sensitivity for cancer of 79% in 1 meta-analysis (85), fair sensitivity for advanced adenomas (approximately 30%), and low 1-time cost (approximately $20). FIT is recommended annually in the United States. The MSTF has recently issued detailed recommendations on the technical performance of FIT (86) and considers FIT an essential element of the CRC screening armamentarium for all practitioners. FIT is commonly the test of choice in programmatic screening, an excellent second choice for practitioners using sequential testing who offer colonoscopy first, and should likely always be one of the tests included in a multiple-options approach. Disadvantages of FIT include the need for repeated testing, which can be problematic in the nonprogrammatic (opportunistic) setting (13), and poor or no sensitivity for serrated class precursor lesions (53). However, there is no evidence that cancers arising through serrated class lesions are less likely to bleed than those arising via adenomas.

FIT-fecal DNA test

The U.S. Food and Drug Administration (FDA) approved a CRC screening test that is a combination of a FIT and markers for abnormal DNA (53) (Cologuard; Exact Sciences; Boston, Mass). The Center for Medicaid & Medicare Services approved the test for reimbursement and recommends performance at 3-year intervals. In a large screening colonoscopy study, patients underwent FIT, the combined FIT-fecal DNA test, and colonoscopy. The FIT-fecal DNA test had a 1-time sensitivity for CRC of 92%. The FIT assay tested in the study had 73.8% sensitivity for cancer, suggesting that most cancer sensitivity of the FIT-fecal DNA test can be achieved without addition of DNA markers. Advantages of the FIT-fecal DNA test include the highest single-time testing sensitivity for cancer of any noninvasive, nonimaging CRC screening test. Also, the study demonstrated 40% sensitivity for SSPs >1 cm in size. The sensitivity of FIT for SSPs was equal to the false-positive rate, indicating no sensitivity.

The major disadvantages of the FIT-fecal DNA test are a substantial decrease in specificity (86.6% in persons with normal colonoscopy or nonadvanced lesions and 89.8% in those with normal colonoscopy), compared with 96% for the FIT test alone, and high cost relative to FIT. Specificity decreased with increasing age and was only 83% in persons aged >65 years. The cost of the FIT-fecal DNA test is approximately $600 for privately insured patients and about $500 for Medicare patients, about 10 times the direct costs of annual FIT. Moreover, there is a further increase in relative costs related to higher numbers of colonoscopies per test. However, specificity of every 3-year testing with the FIT-fecal DNA test may be approximately equal to the anticipated specificity over 3 years of annual FIT testing. There is currently no information regarding the programmatic sensitivity of the FIT-fecal DNA test.

Annual FIT is more effective and less costly than FIT-fecal DNA every 3 years (87), so the FIT-fecal DNA test is unlikely to replace FIT in large organized screening programs. The FIT-fecal DNA test could be particularly appropriate for patients in the 50- to 65-year age group who seek a noninvasive test with very high sensitivity for cancer, because the test has better specificity in this age group. Available evidence suggests that asymptomatic patients with a positive FIT-fecal DNA test and a negative high-quality colonoscopy do not need the colonoscopy repeated or evaluation of the remainder of the GI tract.

CT colonography

CT colonography has replaced double-contrast barium enema as the test of choice for colorectal imaging for nearly all indications. CT colonography is more effective than barium enema and better tolerated (88, 89).

Advantages of CT colonography include a lower risk of perforation compared with colonoscopy and sensitivity of 82 to 92% for adenomas ≥1 cm in size (88, 89, 90, 91). Disadvantages of CT colonography include the use of bowel preparation in most centers in the United States. CT colonography can be performed with laxative-free protocols, but this results in clear reductions in sensitivity relative to colonoscopy (91), including for large polyps. The sensitivity of CT colonography for polyps <1 cm is less than colonoscopy (88, 89, 90, 91), and detection of flat (92) and serrated lesions (93) are major deficiencies of CT colonography. Detection of extracolonic findings by CT colonography is common, and these findings have been classified by the American College of Radiology according to their clinical relevance (94). Radiation exposure is generally viewed as a disadvantage of CT colonography (14). Evidence that CT colonography reduces CRC incidence or mortality is lacking.

Even in centers where CT colonography has long been available, the impact of CT colonography is limited. At one university, after full development of a CT colonography program, CT colonography accounted for about 10% of colorectal imaging studies, even with the availability of insurance coverage (95, 96). Primary care physicians view the need for frequent follow-up colonoscopy examinations and management of incidental extracolonic findings as major factors limiting the utility of CT colonography (96). In general, despite an extensive literature investigating the performance of CT colonography, the test has limited impact on CRC screening compliance (95). However, CT colonography appeals to a niche of patients who are willing to undergo bowel preparation and are concerned about the risks of colonoscopy. When used, the recommended interval is 5 years in patients with normal CT colonography. We continue to recommend that patients with polyps ≥6 mm in size at CT colonography undergo colonoscopy (1).

Flexible sigmoidoscopy

Randomized controlled trials confirm reductions in distal colon or rectosigmoid cancer incidence and/or mortality of 29 to 76% with flexible sigmoidoscopy (66, 97, 98, 99). Flexible sigmoidoscopy can prevent a small fraction (14%) of proximal colon cancers, if liberal criteria are used to indicate colonoscopy based on flexible sigmoidoscopy findings (66). Advantages of flexible sigmoidoscopy include disproportionately lower cost and risk compared with colonoscopy, a more limited bowel preparation, and no need for sedation. Disadvantages of flexible sigmoidoscopy include a lower benefit in protection against right-sided colon cancer compared with the level of protection achieved in case-control and cohort studies using colonoscopy. Also, the absence of sedation leads to a low satisfaction experience for patients, such that they are less willing to repeat the examination compared with colonoscopy (100). Further, the concept of examining only part of the colon has been unpopular in the United States, so that screening by flexible sigmoidoscopy has almost disappeared from opportunistic screening settings (9). Some groups have endorsed the combination of flexible sigmoidoscopy plus FIT for screening (14), but compliance challenges associated with completing 2 screening tests and the dramatic decline in screening flexible sigmoidoscopy make significant uptake of this combination unlikely.

Flexible sigmoidoscopy when used is often recommended at 5-year intervals. However, endoscopic screening in general is more effective in the left than the right side of the colon, and there is no clear reason why flexible sigmoidoscopy should not be recommended at 10-year intervals, similar to the recommendation for colonoscopy. The MSTF considers that either 5- or 10-year intervals are acceptable but favors 10-year intervals.

Capsule colonoscopy

Capsule colonoscopy has been approved by the FDA for imaging the proximal colon in patients with previous incomplete colonoscopies and more recently for patients who need colorectal imaging but who are not candidates for colonoscopy or sedation. Capsule colonoscopy is not approved by the FDA for screening average-risk persons. Advantages of capsule colonoscopy are the achievement of endoscopic imaging without an invasive procedure and avoiding the risks of colonoscopy. Disadvantages are that the bowel preparation is more extensive than that for colonoscopy. Also, because the logistics of performing same-day colonoscopy on patients with positive capsule studies are quite difficult, most patients with positive studies will require re-preparation and colonoscopy on a separate day. In a large screening trial in 884 patients, capsule colonoscopy had 88% sensitivity for detecting patients with a conventional adenoma ≥6 mm in size but was ineffective for the detection of serrated lesions, and 9% of patients had technically failed examinations for inadequate cleansing or rapid transit of the capsule (101).

Overall, the burden associated with bowel preparation and the relative superiority of colonoscopy are such that capsule colonoscopy would be expected to appeal to a niche population concerned about the risks of colonoscopy, in a fashion similar to CT colonography. Currently, lack of FDA approval for screening and lack of reimbursement are major obstacles to its use.

Septin9 assay

The first FDA-approved serum test for CRC screening is the Septin9 assay (Epigenomics, Seattle, Wash). In a large screening colonoscopy study, this test had a sensitivity of 48% for detection of CRC and no sensitivity for detection of precancerous polyps (102). The test is expensive relative to FIT.

The advantage of the Septin9 test is that it is a serum assay and is at least potentially more convenient for patients. Some patients who refused colonoscopy preferred this test over FIT (103).

Disadvantages of the Septin9 assay are markedly inferior performance characteristics compared with FIT, including lower sensitivity for cancer, inability to detect advanced adenomas (104), and low cost-effectiveness relative to other screening tests (105). The test appears to have higher sensitivity for late-stage compared with early-stage cancer (102). The willingness of patients with positive Septin9 tests to undergo colonoscopy remains uncertain. The uncertainties regarding the true clinical utility of Septin 9 makes shared decision-making difficult. Clinicians should inform patients of the uncertain benefits of this test on CRC mortality, the inability of the assay to detect polyps, and the array of superior alternatives. The best frequency for performing the test is uncertain. Given these limitations, the MSTF suggests that Septin9 not be used for screening.

Cost issues

A consistent finding is that CRC screening by any available modality is cost-effective compared with no screening (106, 107), and in some models screening results in cost savings. This finding relates in part to the high costs of CRC treatment. Numerous modeling studies have addressed the relative cost-effectiveness of 2 or more screening tests. The conclusions of the models frequently vary, likely depending in part on the assumptions of the respective models. For example, different models comparing colonoscopy and CT colonography have had variable conclusions (108). Consistent trends reveal that FIT performs well compared with other screening tests (106, 107, 109). Colonoscopy also performs well in most models (106, 107, 108, 110), and, in general, the traditional tests are more cost-effective than the newer modalities, including CT colonography, FIT-fecal DNA, capsule colonoscopy, and the Septin9 assay (105, 106, 107, 111, 112, 113). Newer tests could reach cost-effectiveness by substantially increasing compliance (112, 113), but evidence of improved compliance is lacking. Some models support the cost-effectiveness of risk-stratified approaches to screening (114). Screening remains cost-effective in patients into their mid-80s if they have few comorbidities and limited prior screening (115, 116).

Quality of screening

Variable performance of screening tests affects at least colonoscopy, sigmoidoscopy, CT colonography, and FIT. Optimal results in CRC screening cannot be achieved without optimizing the technical performance and reporting of tests and ensuring that patients undergo appropriate follow-up after testing. The MSTF has made detailed recommendations regarding the technical performance of FIT (86) and has previously issued quality recommendations regarding the technical performance of sigmoidoscopy (117) and colonoscopy (118). The recommendations of the MSTF regarding quality in the technical performance of colonoscopy (118) were largely incorporated in quality recommendations from a combined American College of Gastroenterology-American Society for Gastrointestinal Endoscopy Task Force on quality in 2006 (119) and 2015 (120), and the MSTF endorses the American College of Gastroenterology-American Society for Gastrointestinal Endoscopy Task Force recommendations.

The burden of performing high-quality FIT falls largely on primary care physicians and/or the healthcare systems in which they work. In the opportunistic setting there may not be resources allocated to systematically ensure that FIT-positive patients are referred for colonoscopy and that FIT-negative patients are offered repeat testing or to monitor whether compliance with quality targets is adequate (13). Inability to allocate resources to monitor the quality of FIT testing is a factor favoring reliance on sequential testing with colonoscopy the first test offered.

Unlike primary care physicians, the main role of gastroenterologists in the screening process is to perform colonoscopy on patients referred for primary colonoscopy screening or for colonoscopy to evaluate other positive screening tests. As such, a primary task of gastroenterologists is to perform high-quality colonoscopy and cost-effective follow-up. The adenoma detection rate, originally proposed by the MSTF in 2002 (118), has emerged as the most important and highly variable measure of the quality of mucosal inspection during colonoscopy. Two large studies have validated the adenoma detection rate as a predictor of cancer prevention by colonoscopy (67, 68). Measurement of the adenoma detection rate is mandatory to appreciating whether a colonoscopist should be performing screening colonoscopy. Patients should expect a prospective colonoscopist to provide his or her adenoma detection rate, which should meet or exceed recommended minimum thresholds (Table 3).

Practical considerations

No published randomized trials have directly compared and reported the relative effects of different tests on CRC incidence or mortality. Several trials are ongoing, but results are not yet available. When compared using simulation models that are dependent on assumptions about natural history of disease, patient acceptance of screening, and test performance, several tests appear to be similarly effective (121). Therefore, practical considerations are important for informing our recommendations.

A common statement made with regard to CRC screening is that “the best test is the one that gets done.” The MSTF endorses this concept because it is generally better for any person who is eligible to be screened to undergo some screening test rather than not be screened at all. On the other hand, the core concept underlying sequential testing is that offering the “best” test (s) first optimizes the sensitivity and/or cost-effectiveness of screening and still leaves the opportunity to offer other tests when patients decline. As an extreme example, the MSTF considers that equating the Septin9 assay with colonoscopy would be a disservice to patients, because the sensitivity of colonoscopy for cancer and advanced lesions exceeds that of Septin9 by a very large margin. Given these disparities in the performance of individual tests, the MSTF groups the available tests into 3 tiers based on various performance features and costs (Table 4).

Table 4:
Multi-Society Task Force ranking of current colorectal cancer screening tests

The tier 1 tests representing the cornerstone of CRC screening are colonoscopy every 10 years and annual FIT (Table 4). The use of these 2 tests as the primary screening measures provides a framework for screening that is simple and accommodates almost every screening setting. In organized programmatic screening FIT will often be offered as the primary screen, but colonoscopy can be considered as an alternative for patients and physicians who prefer or request it. In the opportunistic setting, colonoscopy will often be preferred when the infrastructure to ensure annual performance of FIT is not available. As noted above, 1 of the most challenging aspects of FIT screening in the opportunistic setting is ensuring repeated annual performance. Using a tier 1 approach that focuses on 2 tests makes the discussion of CRC screening tests between physician and patient manageable and feasible, and, as noted above, expanding the number of options in the initial discussion beyond 2 did not increase screening rates (19). Colonoscopy and FIT can be adapted readily to either the sequential offer of screening (colonoscopy is offered first with FIT reserved for those who decline colonoscopy), the multiple-options approach (colonoscopy and FIT are each discussed with patients, and if both are declined the discussion moves sequentially to tier 2 tests), and the risk-stratified approach (e.g., colonoscopy is offered first to men age >60 and women age >65 with no prior screening, and FIT is offered to persons under these ages and persons with negative prior colonoscopy). Risk stratification may also take into account factors such as cigarette smoking, diabetes, and obesity.

The rationale for placing tests in the tier 2 and 3 categories follows from the discussion above of individual tests. The ranking implies equivalence for tests within each category, but this is not the intent of the MSTF. For example, flexible sigmoidoscopy screening has strong evidence to support its use. However, the steady decline in the use of flexible sigmoidoscopy in the United States (9, 10) suggests that any strong endorsement of flexible sigmoidoscopy is not consistent with the reality of the test’s lack of popularity among patients and poor reimbursement for physicians. The strong evidence base supporting flexible sigmoidoscopy leads us to place the test in the tier 2 category, although we expect that most practitioners using a sequential approach would move to CT colonography or FIT-fecal DNA in patients who decline colonoscopy and FIT, because these tests are less invasive and survey the entire colon.

Performance characteristics alone would place capsule colonoscopy in tier 2. However, offering capsule colonoscopy as a tier 2 test in a sequential methodology currently would often lead to frustration because reimbursement for screening capsule colonoscopy is seldom available at this time, and the test itself is frequently not available. The onerous bowel preparation and the lack of systems to accomplish same-day colonoscopy in most patients with a positive capsule colonoscopy are additional factors placing capsule colonoscopy in the tier 3 category at this time.

In summary, we suggest that the tiered system (Table 4) has numerous advantages. Predominant reliance on tier 1 tests offers modalities with optimal effectiveness, cost-effectiveness, complete colon screening, proven popularity with patients, and a simplified discussion (compared with offering 5-7 different tests) and still leaves room to offer other tests in a sequential fashion. If patients decline colonoscopy and FIT, all tests in tier 2 are acceptable CRC screening tests, but each has deficiencies relative to the tier 1 tests.


  1. We recommend colonoscopy every 10 years or annual FIT as first-tier options for screening the average-risk persons for colorectal neoplasia (strong recommendation; moderate-quality evidence).
  2. We recommend that physicians performing screening colonoscopy measure quality, including the adenoma detection rate (strong recommendation, high-quality evidence).
  3. We recommend that physicians performing FIT monitor quality (strong recommendation, low-quality evidence). The recommended quality measurements for FIT programs are detailed in a prior publication (86).
  4. We recommend CT colonography every 5 years or FIT-fecal DNA every 3 years (strong recommendation, low-quality evidence) or flexible sigmoidoscopy every 5 to 10 years (strong recommendation, high-quality evidence) in patients who refuse colonoscopy and FIT.
  5. We suggest that capsule colonoscopy (if available) is an appropriate screening test when patients decline colonoscopy, FIT, FIT-fecal DNA, CT colonography, and flexible sigmoidoscopy (weak recommendation, low-quality evidence).
  6. We suggest against Septin9 for CRC screening (weak recommendation, low-quality evidence).

Family history of crc and polyps

We recommend that screening in most average-risk persons be initiated at age 50 years. A family history of CRC or certain polyps can modify the recommended starting age and the frequency of screening. The MSTF has previously issued recommendations for screening in persons with Lynch syndrome (34), which is a genetically defined inherited syndrome caused by mutations in 1 or more mismatch repair genes. Patients in families that meet the clinical criteria for hereditary nonpolyposis CRC but have microsatellite-stable CRCs have family colon cancer syndrome X, which has not been genetically defined (122). Persons in families with syndrome X should undergo colonoscopy at least every 3 to 5 years, beginning 10 years before the age at diagnosis of the youngest affected relative.

A family history of CRC in a first-degree relative increases the risk of CRC regardless of the age at diagnosis of the affected relative (123, 124, 125). There is a gradient of risk such that the younger the age of the affected relative, the greater the risk (123, 124, 125). The MSTF has previously used age 60 as a threshold of risk elevation, so that a single first-degree relative diagnosed with CRC at age <60 years warrants both earlier screening and at more-frequent intervals (1). Recent population-based studies (123, 124) and reviews of risk associated with a positive family history (125) support using age at diagnosis of CRC above or below 60 years in the affected first-degree relative as a risk stratifier. We continue to recommend that persons with a family history of CRC in a first-degree relative diagnosed at <60 years undergo colonoscopy every 5 years beginning at age 40 years or 10 years before the age the relative was diagnosed, whichever comes first (Table 5). In a randomized controlled trial, there was a nonsignificant trend toward detection of more advanced neoplasia in subjects with a positive family history who underwent colonoscopy compared with FIT (126). Thus, patients with a positive family history who decline colonoscopy should be offered FIT screening (126).

Table 5:
MSTF recommendations for persons with high-risk family histories not associated with polyp syndromes

The greatest relative risk of CRC appears to be in persons <50 years who have a first-degree relative with CRC diagnosed at <50 years (123, 124, 125). Compliance in young persons with a family history of CRC is suboptimal, and clinicians should make special efforts to ensure that screening occurs. Recent evidence suggests if persons with a single first-degree relative with a family history of CRC reach the age of approximately 60 years without manifesting significant colorectal neoplasia (127), then they are unlikely to be at increased risk of CRC and can be offered the option of expanding the interval between examinations.

When first-degree relatives have documented advanced serrated lesions (SSPs ≥10 mm in size, or an SSP with cytologic dysplasia, or a traditional serrated adenoma ≥10 mm in size), there is no clear evidence as to how to proceed, unless the relative meets criteria for serrated polyposis (46). Currently, we recommend that screening for first-degree relatives of persons with advanced serrated lesions should be similar to the screening of first-degree relatives of persons with advanced conventional adenomas.

Persons with a single first-degree relative with CRC who was diagnosed at age ≥60 years are recommended to begin screening at 40 years (128). However, the tests and intervals for testing are the same as the average-risk screening recommendations (Tables 4 and 5).

We no longer recommend that persons with a family history of adenomas in a first-degree relative undergo early screening, unless there is clear documentation of an advanced adenoma in a first-degree relative. In most cases the patient has no information regarding whether the family member’s adenoma was advanced, and in this case we recommend that it be assumed the adenomas or polyps were not advanced. If a colonoscopy and/or pathology report (s) is available for a family member that documents an advanced adenoma or there is a report of a polyp requiring surgical resection, an advanced adenoma in a family member is considered established. These considerations regarding adequate documentation of advanced precancerous neoplasms in first-degree relatives before intensifying screening apply to documentation of both advanced adenomas and advanced serrated lesions. First-degree relatives with advanced adenomas are recommended to be weighted the same as first-degree relatives with CRC (Table 5). The yield of colonoscopic screening in first-degree relatives of persons with advanced adenomas is substantially increased (129, 130, 131).


  1. We suggest that persons with 1 first-degree relative with CRC or a documented advanced adenoma diagnosed at age <60 years or with 2 first-degree relatives with CRC and/or documented advanced adenomas undergo colonoscopy every 5 years beginning 10 years younger than the age at which the youngest first-degree relative was diagnosed or age 40, whichever is earlier (weak recommendation, low-quality evidence).
  2. We suggest that persons with 1 first-degree relative diagnosed with CRC or a documented advanced adenoma at age ≥60 years begin screening at age 40. The options for screening and the recommended intervals are the same as those for average-risk persons (weak recommendation, very-low-quality evidence).
  3. We suggest that persons with 1 or more first-degree relatives with a documented advanced serrated lesion (SSP or traditional serrated adenoma ≥10 mm in size or an SSP with cytologic dysplasia) should be screened according to above recommendations for persons with a family history of a documented advanced adenoma (weak recommendation, very-low-quality evidence).
  4. We recommend that persons with 1 or more first-degree relatives with CRC or documented advanced adenomas, for whom we recommend colonoscopy, should be offered annual FIT if they decline colonoscopy (strong recommendation, moderate-quality evidence).

Considerations regarding age and crc risk

CRC screening is recommended to begin at age 50 years in most average-risk persons, including in prior recommendations from the MSTF (1). Recent modeling supports this recommendation (121). Several issues related to age and CRC risk warrant specific discussion.

The incidence of CRC is strongly age related and continues to rise with increasing age. Partly because of widespread screening in the United States, the incidence of CRC in falling by 3 to 4% per year in persons age ≥50 years (12). The incidence of CRC in persons under age 50 is increasing in the United States (132, 133). Although the reasons for this rising incidence remain unclear and the relative incidence in persons under age 50 remains low, the increasing incidence of CRC in young people is a major public health concern.

The best course of action with regard to the rising incidence of CRC in young people is currently not certain. When a young person develops fatal CRC, the loss of life years is great. The first step in reducing CRC morbidity and mortality in persons age <50 years is aggressive evaluation (usually colonoscopy) of patients with colorectal symptoms, specifically those with bleeding symptoms: hematochezia, iron deficiency anemia, and/or melena with a negative upper endoscopy. Persons with bleeding symptoms evaluated with tests other than colonoscopy (e.g., sigmoidoscopy) should have a bleeding source identified and treated, and the patient should be followed to resolution of the symptom. Patients who have nonbleeding symptoms (e.g., abnormal bowel habit, change in bowel habit or shape, or abdominal pain) and who have no evidence of bleeding do not have an increased risk of CRC when they undergo colonoscopy (134, 135).

There is currently insufficient evidence to recommend systematic screening in asymptomatic persons <50 years old who lack specific risk factors related to family history or Lynch syndrome. The yield of screening colonoscopy in this age group is low in available studies (136), and the biologic reasons for the increasing incidence of CRC in persons under age 50 years are uncertain. Additional study of the benefits and harms of screening in persons <50 years is warranted, perhaps particularly in persons with known colorectal risk factors such as cigarette smoking, diabetes mellitus, and obesity (137, 138, 139).

Relative to other races, African Americans have lower screening rates for CRC, higher incidence rates, earlier mean age at onset, worse survival and late-stage presentation, and a higher proportion of cancers before age 50 (140, 141, 142, 143). These various effects result from both socioeconomic and biologic factors (144). Two of the member organizations of the MSTF endorsed beginning average-risk screening in African Americans at age 45 (22, 145), and the American College of Physicians recommended beginning at age 40 (146). The scientific rationale for beginning screening earlier includes the higher overall incidence rates and younger mean age at onset of CRC in African Americans (140, 141, 142, 143). A recent joinpoint regression analysis (147) and a MISCAN-Colon microsimulation model (148) both supported screening African Americans approximately 5 years earlier compared with whites. There are few data on the yield of screening in African Americans before age 50 or whether earlier screening improves outcomes. In persons over age 50, some reports have identified a higher risk of advanced polyps in African Americans (149). The recommendations to begin screening earlier have served an important role in stimulating discussion of and research on CRC in African Americans, increasing awareness in physicians of an important public health problem and racial disparity in health outcomes in the United States, and increasing awareness of CRC in African Americans. Increasing screening rates in African Americans generally is an area of obvious importance. Provider recommendation is key (150), and navigation can improve compliance to colonoscopy screening (151). Additional study of the yield of screening in persons under age 50 is needed, particularly in African Americans.

The age to stop screening can be individualized. Screening is potentially beneficial in persons up to age 86 if there has not been previous screening (116) but should be considered in the context of comorbidities and life expectancy. Persons with previously negative screening tests, particularly negative screening colonoscopy, could consider stopping at age 75 years (14). In a variation of this recommendation, the MSTF has recommended that persons with previous negative screening stop when their life expectancy is less than 10 years (1). Thus, the recommendation to stop screening can be reasonably based on patient age and comorbidities.

The wishes of the patient should be considered in uncertain cases. These considerations do not necessarily apply in the surveillance setting, where patients with advanced neoplasia may benefit from surveillance colonoscopy even at an advanced age, depending on comorbidities and the confidence in neoplasia clearing at colonoscopy.


  1. We recommend that screening begin in non-African American average-risk persons at age 50 years (strong recommendation; moderate-quality evidence).
  2. We suggest that screening begin in African Americans at age 45 years (weak recommendation, very-low-quality evidence).
  3. We recommend that adults age <50 years with colorectal bleeding symptoms (hematochezia, unexplained iron deficiency anemia, melena with a negative upper endoscopy) undergo colonoscopy or an evaluation sufficient to determine a bleeding cause, initiate treatment, and complete follow-up to determine resolution of bleeding (strong recommendation, moderate-quality evidence).
  4. We suggest that persons who are up to date with screening and have negative prior screening tests, particularly colonoscopy, consider stopping screening at age 75 years or when life expectancy is less than 10 years (weak recommendation, low-quality evidence).
  5. We suggest that persons without prior screening should be considered for screening up to age 85, depending on consideration of their age and comorbidities (weak recommendation, low-quality evidence).


CRC screening should begin at age 50 years in asymptomatic persons. Colonoscopy every 10 years and annual FIT are currently the first considerations for screening. Colonoscopy every 10 years has advantages in the opportunistic screening setting. Annual FIT is likely to be preferred in organized screening programs. Positioning of the 2 tests can be reasonably based on a sequential offer (colonoscopy first with FIT offered to patients who decline colonoscopy, followed by second-tier tests for patients who decline FIT), a multiple-options approach where both tests are discussed with patients (followed by a sequential offer of second-tier tests to patients who decline both colonoscopy and FIT), or a risk-stratified approach (colonoscopy is offered to patients with a higher pretest probability of neoplasia, and FIT is used in persons with a lower pretest probability of neoplasia).

Persons with a history of CRC or a documented advanced adenoma in a first-degree relative age <60 years or 2 first-degree relatives with these findings at any age are recommended to undergo screening by colonoscopy every 5 years, beginning 10 years before the age at diagnosis of the youngest affected relative, or at age 40, whichever is earlier. Persons with a single first-degree relative diagnosed at ≥60 years with CRC or an advanced adenoma can be offered average-risk screening options beginning at age 40 years.

The incidence of CRC is rising in persons under age 50. Patients under age 50 with bleeding symptoms consistent with a colorectal source should be aggressively evaluated and treated. We suggest that screening begin at age 45 in African Americans. Discontinuation of screening should be considered when patients who are up to date with screening and have had negative screening tests, particularly colonoscopy, reach age 75 years or when life expectancy is <10 years. Persons without prior screening should be considered for screening up to age 85 years, depending on comorbid conditions and life expectancy.


The views expressed in this article are those of the authors and do not necessarily reflect the position or policy of the Department of Veteran Affairs.


1. Levin B, Lieberman DA, McFarland B et al. Screening and surveillance for the early detection of colorectal cancer and adenomatous polyps. Gastroenterology 2008;134:1570–1595.
2. Kahi CJ, Boland CR, Dominitz JA et al. Colonoscopy surveillance after colorectal cancer resection: recommendations of the US multi-society task force on colorectal cancer. Gastrointest Endosc 2016;83:489–498.
3. Lieberman DA, Rex DK, Winawer SJ et al. Guidelines for colonoscopy surveillance after screening and polypectomy. Gastroenterology 2012;143:844–857.
4. Levin TR, Jamieson L, Burley DA et al. Organized colorectal cancer screening in integrated health care systems. Epidemiol Rev 2011;33:101–110.
5. Zavoral M, Suchanek S, Zavada F et al. Colorectal cancer screening in Europe. World J Gastroenterol 2009;15:5907–5915.
6. Cenin DR, St John DJB, Ledger MJN et al. Optimizing the expansion of the National Bowel Cancer Screening Program. Med J Aust 2014;201:456–461.
7. Jensen CD, Corley DA, Quinn VP et al. Fecal immunochemical test program over 4 rounds of annual screening: a retrospective study. Ann Intern Med 2016;164:456–463.
8. Siegel RL, Ward EM, Jemal A. Trends in colorectal cancer incidence rates in the United States by tumor location and stage, 1992-2008. Cancer Epidemiol Biomarkers Prev 2012;21:411–416.
9. Klabunde CN, Joseph DA, King JB et al. Vital signs: colorectal cancer screening test use—United States, 2012. MMWR 2013;62:881–888.
10. Sabatino SS, White MC, Thompson TT et al. Cancer screening test use—United States, 2013. MMWR 2015;64:464–468.
11. Siegel R, Desantis C, Jemal A. Colorectal cancer statistics, 2014. CA Cancer J Clin 2014;64:104–117.
12. Edwards BK, Noone AM, Mariotto AB et al. Annual report to the nation on the status of cancer, 1975-2010, featuring prevalence of comorbidity and impact on survival among persons with lung, colorectal, breast, or prostate cancer. Cancer 2014;120:1290–1314.
13. Liang PS, Wheat CL, Abhat A et al. Adherence to competing strategies for colorectal cancer screening over 3 years. Am J Gastroenterol 2016;111:105–114.
14. US Preventive Services Task ForceBibbins-Domingo K, Grossman DC, Curry SJ et al. Screening for colorectal cancer: US Preventive Services Task Force recommendation statement. JAMA 2016;315:2564–2575.
15. Inadomi JM, Vijan S, Janz NK et al. Adherence to colorectal cancer screening: a randomized clinical trial of competing strategies. Arch Intern Med 2012;172:575–582.
16. Segnan N, Senore C, Andreoni B et al. Randomized trial of different screening strategies for colorectal cancer: patient response and detection rates. J Natl Cancer Inst 2005;97:147–157.
17. Multicentre Australian Colorectal-neoplasia Screening (MACS) Group. A comparison of colorectal neoplasia screening tests: a multicentre community-based study of the impact of consumer choice. Med J Aust 2006;184:546–550.
18. Scott RG, Edwards JT, Fritschi L et al. Community-based screening by colonoscopy or computed tomographic colonography in asymptomatic average-risk subjects. Am J Gastroenterol 2004;99:1145–1151.
19. Griffith JM, Lewis CL, Brenner ART et al. The effect of offering different numbers of colorectal cancer screening test options in a decision aid: a pilot randomized trial. BMC Med Inform Dec Mak 2008;8:4.
20. Canadian Task Force on Preventive Health Care. Recommendations on screening for colorectal cancer in primary care. CMAJ 2016;188:340–348.
21. Rex DK, Johnson DA, Anderson JC et al. American College of Gastroenterology guidelines for colorectal cancer screening. Am J Gastroenterol 2009;104:739–750.
22. ASGE Standards of Practice CommitteeDavila RE, Rajan E et al. ASGE guideline: colorectal cancer screening and surveillance. Gastrointest Endosc 2006;63:546–557.
23. Senore C, Ederle A, Benazzato L et al. Offering people a choice for colorectal cancer screening. Gut 2013;62:735–740.
24. Symonds EL, Pedersen S, Cole SR et al. Improving participation in colorectal cancer screening: a randomized controlled trial of sequential offers of fecal then blood based non-invasive tests. Asian Pac J Cancer Prev 2015;16:8455–8460.
25. Adler A, Geiger S, Keil A et al. Improving compliance to colorectal cancer screening using blood and stool based tests in patients refusing screening colonoscopy in Germany. BMC Gastroenterol 2014;14:183.
26. Rex D. Colonoscopy: the current king of the hill in the USA. Dig Dis Sci 2015;60:639–646.
27. Ma GK, Ladabaum U. Personalizing colorectal cancer screening: a systematic review of models to predict risk of colorectal neoplasia. Clin Gastroenterol Hepatol 2014;12:1624–1634.
28. Imperiale TF, Monahan PO, Stump TE et al. Derivation and validation of a scoring system to stratify risk for advanced colorectal neoplasia in asymptomatic adults: a cross-sectional study. Ann Intern Med 2015;163:339–346.
29. Chiu HM, Ching JY, Wu KC et al. A risk-scoring system combined with a fecal immunochemical test is effective in screening high-risk subjects for early colonoscopy to detect advanced colorectal neoplasms. Gastroenterology 2016;150:617–625.
30. Winawer SJ, Zauber AG, Ho MN. Prevention of colorectal cancer by colonoscopic polypectomy. The National Polyp Study Workgroup. N Engl J Med 1993;329:1977–1981.
31. Zauber AG, Winawer SJ, O'Brien MJ et al. Colonoscopic polypectomy and long-term prevention of colorectal-cancer deaths. N Engl J Med 2012;366:687–696.
32. Brenner H, Hoffmeister M, Stegmaier C et al. Risk of progression of advanced adenomas to colorectal cancer by age and sex: estimates based on 840,149 screening colonoscopies. Gut 2007;56:1585–1589.
33. Rex DK, Ahnen DJ, Baron JA et al. Serrated lesions of the colorectum: review and recommendations from an expert panel. Am J Gastroenterol 2012;107:1315–1329.
34. Giardiello FM, Allen JI, Axilbund JE et al. Guidelines on genetic evaluation and management of Lynch syndrome: a consensus statement by the U.S. Multi-Society Task Force on Colorectal Cancer. Gastrointest Endosc 2014;80:197–220.
35. Soetikno R, Kaltenbach T, Rouse RV et al. Prevalence of nonpolypoid (flat and depressed) colorectal neoplasms in asymptomatic and symptomatic adults. JAMA 2008;299:1027–1035.
36. Ponugoti PL, Cummings OW, Rex DK. Risk of cancer in small and diminutive colorectal polyps. Dig Liver Dis 2017;49:530–534.
37. Lasisi F, Mouchli A, Riddell R et al. Agreement in interpreting villous elements and dysplasia in adenomas less than one centimeter in size. Dig Liver Dis 2013;45:1049–1055.
38. Rex DK, Alikhan M, Cumming O et al. Accuracy of pathologic interpretation of colorectal polyps by general pathologists in community practice. Gastrointest Endosc 1999;50:468–474.
39. Ponugoti P, Lin J, Odze R et al. Prevalence of sessile serrated adenoma/polyp in hyperplastic appearing diminutive rectosigmoid polyps. Gastrointest Endosc 2016;85:622–627.
40. Abdeljawad K, Vemulapalli KC, Kahi CJ et al. Sessile serrated polyp prevalence determined by a colonoscopist with a high lesion detection rate and an experienced pathologist. Gastrointest Endosc 2015;81:517–524.
41. Ijspeert JE, de Wit K, van der Vlugt M et al. Prevalence, distribution and risk of sessile serrated adenomas/polyps at a center with a high adenoma detection rate and experienced pathologists. Endoscopy 2016;48:740–746.
42. Hetzel JT, Huang CS, Coukos JA et al. Variation in the detection of serrated polyps in an average risk colorectal cancer screening cohort. Am J Gastroenterol 2010;105:2656–2664.
43. Kahi CJ, Hewett DG, Norton DL et al. Prevalence and variable detection of proximal colon serrated polyps during screening colonoscopy. Clin Gastroenterol Hepatol 2011;9:42–46.
44. Tinmouth J, Henry P, Hsieh E et al. Sessile serrated polyps at screening colonoscopy: have they been underdiagnosed? Am J Gastroenterol 2014;109:1698–74.
45. Payne SR, Church TR, Wandell M et al. Endoscopic detection of proximal serrated lesions and pathologic identification of sessile serrated adenomas/polyps vary on the basis of center. Clin Gastroenterol Hepatol 2014;12:1119–1126.
46. Snover D, Ahnen D, Burt RW et al. Serrated polyps of the colon and rectum and serrated (“hyperplastic”) polyposis. In: Bozman FT, Carneiro F, Hruban RH, et al. editors. WHO classification of tumours. Pathology and genetics. Tumors of the digestive system. Springer-Verlag: Berlin. 2010.
47. Nanda KS, Tutticci NG, Burgess N et al. Caught in the act: endoscopic characterization of sessile serrated adenomas with dysplasia. Gastrointest Endosc 2014;79:864–870.
48. Sheridan TB, Fenton H, Lewin MR et al. Sessile serrated adenomas with low and high grade dysplasia and early carcinomas: an immunohistochemical study of serrated lesions “caught in the act.”. Am J Clin Pathol 2006;126:564–571.
49. Lash RH, Genta RM, Sculer CM. Sessile serrated adenomas: prevalence of dysplasia and carcinoma in 2139 patients. J Clin Pathol 2010;63:681–686.
50. Bettington M, Walker N, Rosty C et al. Clinicopathological and molecular features of sessile serrated adenomas with dysplasia or carcinoma. Gut 2017;66:97–106.
51. Kahi C, Vemulapalli KC, Snover DC et al. Findings in the distal colorectum are not associated with proximal advanced serrated lesions. Clin Gastroenterol Hepatol 2015;13:345–351.
52. IJspeert JE, Tutein Nolthenius CJ, Kuipers EJ et al. CT-colonography vs. colonoscopy for detection of high-risk sessile serrated polyps. Am J Gastroenterol 2016;111:516–522.
53. Imperiale TF, Ransohoff DF, Itzkowitz SH et al. Multitarget stool DNA testing for colorectal-cancer screening. N Engl J Med 2014;370:1287–1297.
54. Brenner H, Chang-Claude J, Seiler CM et al. Long-term risk of colorectal cancer after negative colonoscopy. J Clin Oncol 2011;29:3761–3767.
55. Singh H, Nugent Z, Demers AA et al. The reduction in colorectal cancer mortality after colonoscopy varies by site of the cancer. Gastroenterology 2010;139:1128–1137.
56. Kahi CJ, Imperiale TF, Juliar BE et al. Effect of screening colonoscopy on colorectal cancer incidence and mortality. Clin Gastroenterol Hepatol 2009;7:770–775.
57. Brenner H, Chang-Claude J, Seiler CM et al. Protection from colorectal cancer after colonoscopy: a population-based, case-control study. Ann Intern Med 2011;154:22–30.
58. Doubeni CA, Weinmann S, Adams K et al. Screening colonoscopy and risk for incident late-stage colorectal cancer diagnosis in average-risk adults: a nested case-control study. Ann Intern Med 2013;158:312–320.
59. Brenner H, Chang-Claude J, Jansen L et al. Reduced risk of colorectal cancer up to 10 years after screening, surveillance or diagnostic colonoscopy. Gastroenterology 2014;146:709–717.
60. Mulder SA, van Soest EM, Dieleman JP et al. Exposure to colorectal examinations before a colorectal cancer diagnosis: a case-control study. Eur J Gastroenterol Hepatol 2010;22:437–443.
61. Baxter NN, Goldwasser MA, Paszat LF et al. Association of colonoscopy and death from colorectal cancer. Ann Inern Med 2009;150:1–8.
62. Baxter NN, Warren JL, Barrett MJ et al. Association between colonoscopy and colorectal cancer mortality in a US cohort according to site of cancer and colonoscopist specialty. J Clin Oncol 2012;30:2664–2669.
63. Nishihara R, Wu K, Lochhead P et al. Long-term colorectal cancer incidence and mortality after lower endoscopy. N Engl J Med 2013;369:1095–1105.
64. Doubeni CA, Corley DA, Quinn VP et al. Effectiveness of screening colonoscopy in reducing the risk of death from right and left colon cancer: a large community-based study. Gut. Epub 2016 http:/
65. Mandel JS, Church TR, Bond JH. The effect of fecal occult-blood screening on the incidence of colorectal cancer. N Engl J Med 2000;343:1603–1607.
66. Schoen RE, Pinsky PF, Weissfeld JL et al. Colorectal-cancer incidence and mortality with flexible sigmoidoscopy. N Engl J Med 2012;366:2345–2357.
67. Kaminski MF, Regula J, Kraszewska E et al. Quality indicators for colonoscopy and the risk of interval cancer. N Engl J Med 2010;362:1795–1803.
68. Corley DA, Jensen CD, Marks AR et al. Adenoma detection rate and risk of colorectal cancer and death. N Engl J Med 2014;370:1298–1306.
69. Cooper GS, Kou TD, Rex DK. Complications following colonoscopy with anesthesia assistance: a population-based analysis. JAMA Intern Med 2013;173:551–556.
70. Reumkens A, Ronadagh EJ. Bakker, et al. Post-colonoscopy complications: A systematic review, time trends, and meta-analysis of population based studies. Am J Gastroenterol 2016;111:1092–1101.
71. Bahin FF, Rasouli KN, Byth K et al. Prediction of clinically significant bleeding following wide-field endoscopic resection of large sessile and laterally spreading colorectal lesions: a clinical risk score. Am J Gastroenterol 2016;111:1115–1122.
72. Ichise Y, Horiuchi A, Nakayama Y et al. Prospective randomized comparison of cold snare polypectomy and conventional polypectomy for small colorectal polyps. Digestion 2011;84:78–81.
73. Jayanna M, Burgess NG, Singh R et al. Cost analysis of endoscopic mucosal resection vs surgery for large laterally spreading colorectal lesions. Clin Gastroenterol Hepatol 2016;14:271–278.
74. Law R, Das A, Gregory D et al. Endoscopic resection is cost-effective compared with laparoscopic resection in the management of complex colon polyps: an economic analysis. Gastrointest Endosc 2016;83:1248–1257.
75. Shaukat A, Rector TS, Church TR et al. Longer withdrawal time is associated with a reduced incidence of interval cancer after screening colonoscopy. Gastroenterology 2015;149:952–957.
76. Barclay RL, Vicari JJ, Doughty AS et al. Colonoscopic withdrawal times and adenoma detection during screening colonoscopy. N Engl J Med 2006;355:2533–2541.
77. Chen SC, Rex DK. Endoscopist can be more powerful than age and male gender in predicting adenoma detection at colonoscopy. Am J Gastroenterol 2007;102:856–861.
78. Butterly L, Robinson CM, Anderson JC et al. Serrated and adenomatous polyp detection increases with longer withdrawal time: results from the New Hampshire Colonoscopy Registry. Am J Gastroenterol 2014;109:417–426.
79. Mysliwiec PA, Brown ML, Klabunde CN et al. Are physicians doing too much colonoscopy? A national survey of colorectal surveillance after polypectomy. Ann Intern Med 2004;141:264–271.
80. Pohl H, Srivastava A, Bensen SP et al. Incomplete polyp resection during colonoscopy-results of the complete adenoma resection (CARE) study. Gastroenterology 2013;144:74–80.e1.
81. Rex DK, Rahmani EY, Haseman JH et al. Relative sensitivity of colonoscopy and barium enema for detection of colorectal cancer in clinical practice. Gastroenterology 1997;112:17–23.
82. Rabeneck L, Paszat LF, Saskin R. Endoscopist specialty is associated with incident colorectal cancer after a negative colonoscopy. Clin Gastroenterol Hepatol 2010;8:275–279.
83. Hassan C, Rex DK, Zullo A et al. Loss of efficacy and cost-effectiveness when screening colonoscopy is performed by nongastroenterologistss. Cancer 2012;118:4404–4411.
84. Ko CW, Dominitz JA, Green P et al. Specialty differences in polyp detection, removal, and biopsy during colonoscopy. Am J Med 2010;123:528–535.
85. Lee JK, Liles EG, Bent S et al. Accuracy of fecal immunochemical tests for colorectal cancer: systematic review and meta-analysis. Ann Intern Med 2014;160:171–181.
86. Robertson DJ, Lee JK, Boland CR et al. Recommendations on fecal immunochemical testing to screen for colorectal neoplasia: a consensus statement by the US Multi-Society Task Force on colorectal cancer. Gastrointest Endosc 2016;85:2–21.
87. Ladabaum U, Mannalithara A. Comparative effectiveness and cost-effectiveness of a multi-target stool DNA test to screen for colorectal neoplasia. Gastroenterology 2016;151:427–39.e6.
88. Rosman AS, Korsten MA. Meta-analysis comparing CT colonography, air contrast barium enema, and colonoscopy meta-analysis comparing CT colonography, air contrast barium enema, and colonoscopy. Am J Med 2007;120:203–210.
89. Halligan S, Wooldrage K, Dadswell E et al. Computed tomographic colonography versus barium enema for diagnosis of colorectal cancer or large polyps in symptomatic patients (SIGGAR): a multicentre randomised trial. Lancet 2013;381:1185–1193.
90. Johnson CD, Herman BA, Chen MH et al. The National CT Colonography Trial: assessment of accuracy in participants 65 years of age and older. Radiology 2012;263:401–408.
91. Stoop EM, de Haan MC, de Wijkerslooth TR et al. Participation and yield of colonoscopy versus non-cathartic CT colonography in population-based screening for colorectal cancer: a randomized controlled trial. Lancet Oncol 2012;13:55–64.
92. Sakamoto T, Mitsuzaki K, Utsunomiya D et al. Detection of flat colorectal polyps at screening CT colonography in comparison with conventional polypoid lesions. Acta Radiol 2012;53:714–719.
93. IJspeert JE, Tutein Nolthenius CJ, Kuipers EJ et al. CT-colonography vs. colonoscopy for detection of high-risk sessile serrated polyps. Am J Gastroenterol 2016;111:516–522.
94. Zalis ME, Barish MA, Choi JR et al. CT colonography reporting and data system: a consensus proposal. Radiology 2005;236:3–9.
95. Benson M, Pier J, Kraft S et al. Optical colonoscopy and virtual colonoscopy numbers after initiation of a CT colonography program: long term data. J Gastrointestin Liver Dis 2012;21:391–395.
96. Schwartz DC, Dasher KJ, Said A et al. Impact of a CT colonography screening program on endoscopic colonoscopy in clinical practice. Am J Gastroenterol 2008;103:346–351.
97. Atkin WS, Edwards R, Kralj-Hans I et al. Once-only flexible sigmoidoscopy screening in prevention of colorectal cancer: a multicenter randomized controlled trial. Lancet 2010;375:1624–1633.
98. Segnan N, Armaroli P, Bonelli L et al. Once-only sigmoidoscopy in colorectal cancer screening follow-up findings of the Italian Randomized Controlled trial-SCORE. JNCI 2011;103:1310–1322.
99. Hoff G, Grotmol T, Skovlund E et al. Risk of colorectal cancer seven years after flexible sigmoidoscopy screening: randomized controlled trial. BMJ 2009;338:b1846.
100. Zubarik R, Ganguly E, Benway D et al. Procedure-related abdominal discomfort in patients undergoing colorectal cancer screening: a comparison of colonoscopy and flexible sigmoidoscopy. Am J Gastroenterol 2002;97:3056–3061.
101. Rex DK, Adler SN, Aisenberg J et al. Accuracy of capsule colonoscopy in detecting colorectal polyps in a screening population. Gastroenterology 2015;148:948–57.e2.
102. Church TR, Wandell M, Lofton-Day C et al. Prospective evaluation of methylated SEPT9 in plasma for detection of asymptomatic colorectal cancer. Gut 2014;63:317–325.
103. Adler A, Geiger S, Keil A et al. Improving compliance to colorectal cancer screening using blood and stool based tests in patients refusing screening colonoscopy in Germany. BMC Gastroenterology 2014;14:183.
104. Parikh RB, Prasad V. Blood-based screening for colon cancer: a disruptive innovation or simply a disruption? JAMA 2016;315:2519–2520.
105. Ladabaum U, Alvarez-Osorio L, Rösch T et al. Cost-effectiveness of colorectal cancer screening in Germany: current endoscopic and fecal testing strategies versus plasma methylated Septin 9 DNA. Endosc Int Open 2014;2:e96–104.
106. Patel SS, Kilgore ML. Cost effectiveness of colorectal cancer screening strategies. Cancer Control 2015;22:248–258.
107. Landsdorp-Vogelaar I, Knudsen AB, Brenner H. Cost-effectiveness of colorectal cancer screening. Epidemiol Rev 2011;33:88–100.
108. Hanly P, Skally M, Fenlon H et al. Cost-effectiveness of computed tomography colonography in colorectal cancer screening: a systematic review. Int J Technol Assess Health Care 2012;28:415–423.
109. Greuter MJ, Berkhof J, Fireman RJ et al. The potential of imaging techniques as a screening tool for colorectal cancer: a cost-effectiveness analysis. Br J Radiol 2016;89:20150910.
110. Wong MC, Ching JY, Chan VC et al. The comparative cost-effectiveness of colorectal cancer screening using fecal immunochemical test vs colonoscopy. Scientific Reports 2015
111. Skally M, Hanly P, Sharp L et al. Cost-effectiveness of fecal DNA screening for colorectal cancer: a systematic review and quality appraisal of the literature. Appl Econ Health Policy 2013;11:181–192.
112. Knudsen AB, Landsdorp-Vogelaar I, Rutter LM et al. Cost-effectiveness of computed tomographic colonography screening for colorectal cancer in the medicare population. J Natl Cancer Inst 2010;102:1238–1252.
113. Hassan C, Zullo A, Winn S. Cost-effectiveness of capsule endoscopy in screening for colorectal cancer. Endoscopy 2008;40:414–421.
114. Dinh T, Ladabaum U, Alperin P et al. Health benefits and cost-effectiveness of a hybrid screening strategy for colorectal cancer. Clin Gastroenterol Hepatol 2013;11:1158–1166.
115. Jenkins M. Colorectal cancer screening is cost-effective in the elderly who have had less intense prior screening, high baseline risk of colorectal cancer and less comorbidities. Evid Based Med 2016;21:182.
116. van Hees F, Habbema JD, Meester RG et al. Should colorectal cancer screening be considered in elderly persons without previous screening? A cost-effectiveness analysis Ann Intern Med 2014;160:750–759.
117. Levin TR, Farraye FA, Schoen RE et al. Quality in the technical performance of screening flexible sigmoidoscopy: recommendations of an international multi-society task group. Gut 2005;54:807–813.
118. Rex DK, Bond JH, Winawer S et al. Quality in the technical performance of colonoscopy and the continuous quality improvement process for colonoscopy: recommendations of the US Multi-Society Task Force in Colorectal Cancer. Am J Gastroenterol 2002;97:1296–1308.
119. Rex DK, Petrini JL, Baron TH et al. Quality indicators for colonoscopy. Gastrointest Endosc 2006;63 (4 Suppl): S16–S28.
120. Rex DK, Schoenfeld PS, Cohen J et al. Quality indicators for colonoscopy. Am J Gastroenterol 2015;110:72–90.
121. Knudsen AB, Zauber AG, Rutter CM et al. Estimation of benefits, burden, and harms of colorectal cancer screening strategies; modeling study for the US Preventive Services Task Force. JAMA 2016;315:2595–2609.
122. Lindor NM. Familial colorectal cancer type X: the other half of hereditary nonpolyposis colon cancer syndrome. Surg Oncol Clin N Am 2009, 637–645.
123. Samadder NJ, Smith KR, Hanson H. Increased risk of colorectal cancer among family members of all ages, regardless of age of index case at diagnosis. Clin Gastroenterol Hepatol 2015;13:2305–2311.
124. Samadder NJ, Curtin K, Tuohy TMF et al. Increased risk of colorectal neoplasia among family members of patients with colorectal cancer: a population-based study in Utah. Gastroenterology 2014;147:814–821.
125. Lowery JT, Ahnen DJ, Schroy PC et al. Understanding the contribution of family history to colorectal cancer risk and its clinical implications: a state-of-the-science review. Cancer 2016;122:2633–2645.
126. Quintero E, Carrillo M, Gimeno-Garcia AZ et al. Equivalency of fecal immunochemical tests and colonoscopy in familial colorectal cancer screening. Gastroenterology 2014;147:1021–1030.
127. Schoen RE, Razzak A, Yu KJ et al. Incidence and mortality of colorectal cancer in individuals with a family history of colorectal cancer. Gastroenterology 2015;149:1438–1445.
128. Fuchs CS, Giovannucci EL, Colditz GA et al. A prospective study of family history and the risk of colorectal cancer. N Engl J Med 1994;331:1669–1674.
129. Cottet V, Pariente A, Nalet B et al. Colonoscopic screening of the first-degree relatives of patients with large adenomas; increased risk of colorectal tumors. Gastroenterology 2007;133:1086–1092.
130. Wong MC, Ching JY, Chiu HM et al. Risk of colorectal neoplasia in individuals with self-reported family history: a prospective colonoscopy study from 16 Asia-Pacific regions. Am J Gastroenterol 2016;111:1621–1629.
131. Ng SC, Lau JYW, Chan FKL et al. Risk of advanced adenomas in siblings of individuals with advanced adenomas: a cross-sectional study. Gastroenterology 2016;150:608–616.
132. Ahnen DJ, Wade SW, Jones WF et al. The increasing incidence of young-onset colorectal cancer: a call to action. Mayo Clin Proc 2014;89:216–224.
133. Printz C. Colorectal cancer incidence increasing in young adults. Cancer 2015;121:1912–1913.
134. Rex DK, Mark D, Clarke B et al. Flexible sigmoidoscopy plus air-contrast barium enema versus colonoscopy for evaluation of symptomatic patients without evidence of bleeding. Gastrointest Endosc 1995;42:132–138.
135. Lieberman DA, De Garmo PL, Fleischer DE. Colonic neoplasia in patients with nonspecific GI symptoms. Gastrointest Endosc 2000;51:647–651.
136. Imperiale TF, Wagner DR, Lin CY et al. Results of screening colonoscopy among persons 40 to 49 years of age. N Engl J Med 2002;346:1781–1785.
137. Bardou M, Barkun AN, Martel M. Obesity and colorectal cancer. Gut 2013;62:933–947.
138. Hann LM, Jacobs EJ, Thun MJ. The association between cigarette smoking and risk of colorectal cancer in a large prospective cohort from the United States. Cancer Epidemiol Biomarkers Prev 2009;18:3362–3367.
139. Guraya SY. Association of type 2 diabetes mellitus and the risk of colorectal cancer: A meta-analysis and systematic review. World J Gastroenterol 2015;21:6026–6031.
140. Williams R, White P, Nieto J et al. Colorectal cancer in African Americans: an update. Clin Transl Gastroenterol 2016;7:e185.
141. QuickStats: Colorectal cancer screening among adults aged 50-75 years, by race/ethnicity—National Health interview Study, United States, 2000-2015. MMWR Morb Mortal Wkly Rep 2016;65:1042.
142. Carethers JM. Screening for colorectal cancer in African-Americans: determinants and rationale for an earlier age to commence screening. Dig Dis Sci 2015;60:711–721.
143. Ashktorab H, Vimenay K, Brim H et al. Colorectal cancer in young African Americans: is it time to revisit guidelines and prevention? Dig Dis Sci 2016;61:3026–3030.
144. Lin J, Qiu M, Xu R et al. Comparison of survival and clinicopathologic features in colorectal cancer among African American, Caucasian, and Chinese patients treated in the United States: Results from the surveillance epidemiology and end results (SEER) database. Oncotarget 2015;6:33935–33943.
145. Agrawal S, Bhupinderjit A, Bhutani MS et al. Colorectal cancer in African Americans. Am J Gastroenterol 2005;100:515–523.
146. Qaseem A, Denberg TD, Hopkins RH. Screening for colorectal cancer; a guidance statement from the American College of Physicians. Ann Intern Med 2012;156:378–386.
147. Paquette IM, Ying J, Shah SA et al. African Americans should be screened at an earlier age for colorectal cancer. Gastrointest Endosc 2015;82:878–883.
148. Landsdorp-Vogelaar I, van Ballegooijen M, Zauber AG et al. Individualizing colonoscopy screening by sex and race. Gsatrointest Endosc 2009;70:96–108.
149. Lieberman DA, Williams JL, Holub JL et al. Race, ethnicity, and sex affect risk for polyps >9 mm in average-risk individuals. Gastroenterology 2014;147:351–358.
150. Thompson VL, Lander S, Xu S et al. Identifying key variables in African American adherence to colorectal cancer screening: the application of data mining. BMC Public Health 2014;14:1173.
151. Horne HN, Phelan-Emrick DF, Pollack CE et al. Effect of patient navigation on colorectal cancer screening in a community-based randomized controlled trial of urban African American adults. Cancer Causes Control 2015;26:239–246.
© The American College of Gastroenterology 2017. All Rights Reserved.