Colon Cancer Screening


Definition/Introduction

Colorectal carcinoma (CRC) is the third most common non-skin cancer in the United States after lung cancer in both men and women, with an annual incidence of 42.9 per 100,000 people. It accounts for 8% of cancer-related deaths in the US alone.[1] 

Its prevalence and incidence vary worldwide, with Australia and New Zealand having the highest incidence, followed by North America and Europe. Africa and South-Central Asia have the lowest incidence.

Such a pattern only extrapolates that CRC incidence is attributed to dietary factors along with genetic and environmental factors. It also displays a strong correlation with increased age, the maximum rate at the age above 75 years, and the lowest below 40 years. Males are affected more than females. African Americans have the highest incidence, and Asian Pacific Islanders have the lowest.

Screening is the process of looking for cancer in patients that have no symptoms. Several tests are available to screen for colorectal cancer. These tests can be divided into stool-based tests and visual exams. Any abnormal test result should be followed up with a colonoscopy. If cancer of the colon is caught early, the patient usually has a better outcome.

Issues of Concern

With the advent of newer and better screening tools, CRC related mortality rate has decreased, on average, by about 2.7% between 2004 and 2013. It is expected to decrease further to about 38% for 50 to 74-year-olds and about 45% for those older than 75 years by 2030.[2] However, for unknown reasons, data from the United States Surveillance, Epidemiology, and End Results (SEER) database suggests that the incidence has been increasing among younger adults below 50 years of age.[3] Rates have increased constantly at a rate of 2 percent yearly from 1992 through 2013.[3] Hence, delivering more effective and robust screening is the best preventive instrument. 

Recently, a gradual shift towards right-sided or proximal colon cancers has been seen both in the United States[4][5] and internationally. Mostly, the incidence of cecal primary malignancies has increased.[6] This can be attributed to the anatomic distribution of CRCs as well as to improvements in diagnosis and treatment by screening and removal of adenomatous polyps in the distal colon. Cancer biology also seems to play a role in this recent shift since serrated adenomas, which exclusively have BRAF-V600E mutations, cause lesions that are flatter and difficult to visualize endoscopically and are more common in the right colon.[7] Wide-spread, compliant and flexible screening is the best step to prevent CRC mortality in the near future, given present epidemiological evidence. 

Pathogenesis

Most CRCs begin as protuberances tethered to the inner surface of the colon or rectum, clinically known as “polyps.” These are mainly of two types: flat or raised, relative to the inner-epithelial lining.

Raised polyps show two distinctive growth patterns of mushroomed growth:

  • With a stalk (pedunculated polyps)
  • Without a stalk (sessile polyps)

About 10 percent of CRC patients carry one or more pathogenic “non-Lynch syndrome mutations,”  including mutations in high-penetrance genes such as APC, bi-allelic MUTYH, BRCA1, BRCA2, PALB2, CDKN2A, and TP53.[8]

Right-sided CRCs tend to be diagnosed in advanced stages compared to left-sided, as the cecum and right colon have a larger caliber, and stool is more liquid, causing fewer symptoms of partial obstruction such as pain, swelling, and constipation. Blood in stools (hematochezia or melena) isn’t readily observed and comes much later as compared to the left side, making screening tools pivotal in management for early detection and therapy.[8][7]

Risk factors for CRC

Risk factor assessment helps to categorize the patient as high, average, or low-risk. Aggressive multiple interval-based testing starts as early as the teenage years[9] in patients with a positive family history or co-existing genetic cancer syndromes. A relaxed approach toward screening and further management can be seen in the majority of cases who are at average risk.[10]

1.) Family history (especially first-degree relatives)

  • Colorectal carcinoma
  • Pre-cancerous adenomas

2.) Genetic cancer syndromes

  • Familial adenomatous polyposis (FAP and its variants Gardner and Turcot syndrome)
  • Lynch syndrome
  • Hereditary non-polyposis colorectal cancer (HNPCC)
  • Peutz-Jeghers syndrome
  • Juvenile polyposis 

3.) Medical history

  • Previously resected or diagnosed adenomatous colorectal polyps; or any of the above mentioned genetic-cancer syndromes
  • Cystic fibrosis[11]
  • Inflammatory bowel diseases like Crohn disease or ulcerative colitis
  • Diabetes mellitus and insulin resistance[12]
  • Abdomino-pelvic radiation for an earlier cancer in childhood or adolescence (as suggested by Children Oncology Group- COG)
  • HIV infection in men[13]

4.) Personal history

  • Chronic alcohol use disorder
  • Smoking
  • Physical inactivity
  • Obesity
  • Poor diet (low fiber; high amounts of red and processed meat consumption)

 5.) Race

  • Higher incidence and mortality among African-Americans, particularly men. CRC occurrence is higher in African-Americans less than 50 years of age. Hence earlier screening, starting from the age of 45 years, is recommended by USPSTF.[1]

Clinical Significance

Screening Tools

The various modalities for early detection of CRCs are as follows:

Stool-based Tests

  • Fecal immuno-chemical test (FIT)
  • Guaiac fecal occult blood test (gFOBT), also known as HSgFOBT (high-sensitivity guaiac-based fecal occult blood test)
  • Stool DNA test (FIT-DNA): also known as MT-sDNA test (Multi-targeted-stool DNA test) 

Visualization-based Tests

  • Sigmoidoscopy
  • Colonoscopy
    • Optical- standard 
    • Virtual- Radiological: CTC and Capsule colonoscopy.
  • Barium enema       

Blood-based Test

  • Methylated SEPT-9

Age to Initiate Screening

The U.S. Preventive Services Task Force (USPSTF) and many other expert councils recommend initiating screening for average-risk patients at 45 years of age due to high early-onset incidence.[1] For those with high-risk attributes (positive family history or cancer syndromes), screening can be initiated as early as the teenage years.[9] Screening for those with a positive family history is recommended to start 10 years before the age of diagnosis of the family member. USPSTF doesn't recommend routine CRC screening in adults 86 years and older.

Contraindications for Screening

Contraindications might vary depending upon the screening method. Most stool-based tests can be carried out easily. However, other screening methods involve sedation, consumption of contrast, and further instrumentation of the colon. Bowel preparation is a vital prerequisite, using either a laxative or non-laxative method. The type of bowel preparation should be determined based on the patient's medical conditions. Colonoscopy should generally be avoided if there is a concern for bowel perforation. Care should be taken for the following conditions:  

  1. Active colonic inflammation (e.g., acute diarrhea, active inflammatory bowel disease)
  2. Symptomatic colon-containing abdominal wall hernia
  3. Recent acute diverticulitis
  4. Recent colorectal surgery
  5. Recent deep endoscopic biopsy/polypectomy/mucosectomy
  6. Known or suspected colonic perforation
  7. Symptomatic or high-grade bowel obstruction 
  8. The patient is unwilling to give consent
  9. The patient is uncooperative or unable to achieve sedation 
  10. Risk of colonic perforation in patients undergoing colonoscopies, such as those with toxic mega-colon and fulminant colitis[14]
  11. Other contraindications limited to colonoscopy include- inadequate bowel preparation, recent myocardial infarction, arrhythmias, or medically unstable patients. 

Evidence of Effectiveness of Various Screening Tests:

1.) Guaiac FOBT (gFOBT) vs. Fecal Immune-chemical Test (FIT)

Evidence of Effectiveness

  1. FIT is more sensitive than gFOBT for colon lesions.[15]
  2. High-sensitivity gFOBT has a sensitivity of 62% to 79% and a specificity of 87% to 96% for detecting colorectal cancer.[16]
  3. FIT has a sensitivity of 79% to 88% and a specificity of 91% to 93%.
  4. Evidence suggests a decline in the mortality rate by 15% to 33% when gFOBT/FIT is performed every 1- 2 years in people aged 50 to 80 years.[16]
  5. FIT has high sensitivity (80%) for detecting CRC, while only 25% to 56% sensitivity for detecting advanced adenomas.[16][17]

2.) Stool DNA Test

Evidence of Effectiveness

  1. Its sensitivity and specificity were 92% to 95% and 84% to 95%, respectively. Its sensitivity to detect advanced precancerous lesions such as advanced adenomas and sessile serrated polyps measuring less than 1 cm was 42% and its specificity to detect "all nonadvanced findings," including non-neoplastic findings, was 87%.[18]
  2. It displays a higher sensitivity than FIT (92% vs. 74%), with more false positives. However, it detected less than half of advanced adenomas (42%), limiting its preventive role due to its low specificity (87% to 90%).[19]
  3. No evidence of mortality reduction currently exists.     

3.) Sigmoidoscopy

Evidence of Effectiveness

  1. Evidence suggests that regular screening with sigmoidoscopy alone after 50 years of age (55 to 64 years) significantly lowers mortality related to rectal or lower colonic cancer by 60% to 70%.[20][21]
  2. There is a reduction of CRC incidence by 33 to 42 percent through various randomized controlled trials.[20][22] 

4.) Colonoscopy

Evidence of Effectiveness

  1. The reduction in CRC incidence and mortality was 31% and 46%, respectively, as established by six observational studies, which further suggested strong evidence of a reduction in incidence and mortality of both distal and proximal colorectal cancers. Sigmoidoscopy only helps in curtailing distal CRC related mortality and incidence.[7]
  2. Colonoscopy is very effective in preventing left-sided CRC than right-sided CRCs, which could also contribute to a shift in the distribution of cancers in the colon.[7]  
  3. The sensitivity of colonoscopy after bowel preparation to detect adenomas 6 mm or larger ranged from 75% to 93%, and specificity ranged from 89% to 91%.[23] 
  4. For adenomatous polyps 6 mm or larger, a systematic review reported the sensitivity of colonoscopy for detection varied from 75 percent to 93 percent. The miss rate for polyps of any size was 22 percent, with rates increasing inversely with the size of the lesion. Adenomas smaller than 5 mm were missed in as many as 25% of patients.[24][25][26]

5.) Colon Capsule Endoscopy

Evidence of Effectiveness

Studies showed that in asymptomatic patients using high-quality optic colonoscopy as the standard, capsule endoscopy identified subjects with more than one adenoma of greater than or equal to 6 mm with a sensitivity of 88 percent and specificity 82 percent, and even higher rates in larger adenomas.[27]

6.) Computed Tomography Colonography

 Evidence of Effectiveness

  1. Even though it's a sophisticated modality when compared to colonoscopy, multiple studies demonstrate a fluctuating sensitivity for CRC lesions, between 67 and 94 percent, while colonoscopy is 92% sensitive. However, CT colonography (CTC) has a very high specificity at 96 to 98 percent.[28]
  2. Patients who underwent both colonoscopy and CTC saw a surge of 14 to 15 non-rectal neoplasms, missed by colonoscopy, which was located on mucosal folds.[29][25]
  3. It can still miss some flattened and small polyps (less than 8 mm).[29]

7.) Methylated SEPT-9

Evidence of effectiveness

  1. It can detect advanced CRC; however, relevance in early-stage detection is yet to be established. The methylated SEPT-9 DNA assay has a sensitivity for CRC of 75 percent and specificity of 87 percent, with increasing detection rates in advanced cancers.[30]
  2. Due to poor sensitivity, its role as a primary screening tool is questionable. It also has a false positive rate of 4.7 percent.[31][30]
  3. There is no evidence yet that this test can reduce CRC deaths. However, as a non-invasive testing option, it can have significantly increased compliance and participation among high-risk groups.[30]

Screening Protocols and Algorithms (Image 1) 

1.) Fecal Occult Blood Test

  1. Since polyps and CRCs have a high propensity to bleed, FOBT can detect occult blood.[19]
  2. Sample collection: The patient is given a stool collection kit or asked to get one from the pharmacy (as per local protocols) and is asked to bring in stool samples (sometimes by mail) within 24 hours of collection, as sensitivity to test declines proportionally to delay.[32][33]
  3. Sample processing: Don't rehydrate samples, as it may falsely increase sensitivity, leading to an increased number of false positives.[33]  

Guaiac FOBT (gFOBT): Consists of guaiac as the main reagent derived from a plant that exclusively grows in the Caribbean. It detects organic heme by oxidation. Therefore, the presence of dietary heme from red meat, peroxidase from some plants, and anti-oxidants like vitamin C or E can lead to false positives. Fasting is advised before the test.

Fecal Immune-Chemical Test (FIT): Employs antibodies to specifically detect human heme-based globin. Dietary and medication restrictions prior to tests aren't required. The test is very specific for detecting colonic/rectal bleeding.

  • Advantages
    • Bowel preparation isn't a pre-requisite.
    • Dietary or medication restrictions are not a prerequisite for FIT. Samples can be collected at home, hence convenience and higher adherence.[34]
    • Cost-effective compared to other CRC screening tests.
    • There is no risk of damage to the colon. 
  • Disadvantages
    • The test does not detect some polyps and cancers.
    • False-positive test results are possible.
    • Dietary restrictions are needed before guaiac FOBT.
    • Additional procedures, such as colonoscopy, may be needed if the results are positive.  

2.) Stool DNA Test

  1. Also known as the FIT-DNA test, it comes as an FDA approved kit. It's a multi-target test that detects occult blood along with nine DNA biomarkers of three genes associated with CRC and advanced adenoma.[18][8]
  2. Sample collection: Like FOBTs, the patient is provided a stool collection kit and asked to collect a stool sample, which can be delivered via mail or can be delivered personally to a laboratory/office, ideally within 72 hours.
  • Advantages
    • No bowel preparation is required.
    • No dietary or medication restrictions as a pre-requisite.
    • Samples can be collected at home, hence convenience and high adherence.
    • No risk of damage to the colon. 
  • Disadvantages
    • More expensive than gFOBT or FIT.
    • Test sensitivity for adenomas is low.
    • False-positive test results can be seen.
    • Additional procedures, such as colonoscopy, is advised if results are positive.  

3.) Sigmoidoscopy

  1. Examination of the rectum and sigmoid colon using a sigmoidoscope, an instrument consisting of a flexible tube with a lens and light source for visualization and a tool for removing tissues (polyp/adenoma) or taking biopsy samples.
  2. The sigmoidoscope is inserted through the anus up to the splenic flexure after insufflating carbon dioxide for better visualization.
  • Advantages
    • Minimal discomfort and complications are rare.
    • Biopsy and polypectomy (removal of a polyp or adenoma) can be performed during the same procedure. 
    • Less extensive cleansing of the colon is required than for colonoscopy, as it only probes the sigmoid colon.
  • Disadvantages
    • Pre-cancerous or CRC lesions in the right colon will be missed due to limited visualization.
    • Bowel preparation by either enema or laxatives is a pre-requisite.
    • Medication and diet changes may be needed before the test.
    • Small risk of bleeding or perforation of the colon lining.
    • Additional procedures, such as colonoscopy, may be needed to detect synchronous lesions.

4.) Colonoscopy

  • A colonoscope is inserted through the anus and through the entire colon ending in the cecum.
  • Abnormal growths can be visualized and can be either removed (polypectomy) in whole, or a small sample can be taken for biopsy in a single procedure.
  • Since the procedure is more invasive than sigmoidoscopy, it requires rigorous bowel preparation and dietary modifications.[35]
  • Advantages
    • One of the most sensitive and definitive methods (gold standard) currently available for the detection of both pre-cancerous adenomas and CRC.
    • It allows for the best visualization of the cecum and the entire colon, unlike sigmoidoscopy.
    • Biopsy and polypectomy can be done in a single procedure.
  • Disadvantages
    • Even though this test is highly sensitive, it still may not detect all small or sessile polyps and cancers.
    • Thorough cleansing of the colon is a pre-requisite.
    • Diet and medication modifications are pre-requisites.
    • Some form of sedation is almost always used. Hence, the patient must have someone to accompany them. Rest and avoiding any work is advised after the procedure. 
    • Small risk of bleeding or perforation of the colon; this risk increases with age, with the presence of other health problems, and when polyps are removed.[14]

5.) Colon Capsule Endoscopy

  1. Approved by the US Food and Drug Administration (FDA) to be used only in patients who had an incomplete colonoscopy. The patient swallows a capsule containing tiny wireless cameras that take images as the capsule traverses the colon.
  • Advantages
    • Colon capsule endoscopy requires bowel preparation; however, it does not require sedation or dietary or medication adjustments.
  • Disadvantages 
    • It doesn't accommodate polypectomy or biopsy and is only meant for lesion visualization. This test appears to have a sensitivity and specificity similar to colonoscopy. However, it is not indicated as a primary screening tool.

6.) Computed Tomography Colonography

  1. The procedure isn't invasive and doesn't require sedation. However, bowel preparation and carbon-dioxide insufflation are still needed for better visualization.
  2. It may additionally require an intravenous catheter for glucagon administration for bowel relaxation. Images are then obtained during a single 32-second breath-hold.[28] 
  • Advantages
    • A minimally invasive procedure, hence little to no risk of damage to the colon.
    • No sedation is required.
  • Disadvantages
    • Thorough cleansing of the colon is a pre-requisite.
    • It can miss small polyps.
    • Additional procedures, such as standard colonoscopy, are advised should CTC come back positive for lesions. 
    • It exposes an already at-risk patient to ionizing radiation and discomfort of contrast with possible allergy. 

7.) Fecal Tagging

  1. It's a laxative-free CTC approach, done by oral administration of a contrast agent over several days before the procedure, making fecal material in the colon distinct from colon tissue by "tagging" it.
  2. Radiographs of the colon are then obtained.
  3. Sensitivity is somewhat lower than conventional CTC with laxative bowel preparation.[28]

8.) Barium Enema

Either single or double-contrast is rarely used, and neither is recommended by any other expert group, due to its poor screening indices and because of the advent of better endoscopic and CTC procedures with better results.

Screening Frequencies and Ideal Intervals for Surveillance and Follow-up (Image 2)

1.) Guaiac FOBT (gFOBT) & Fecal Immune-chemical Test (FIT) 

Frequency of testing: Experts recommend sigmoidoscopy every 5 years for people at average risk who have had negative test results.[34]

2.) Stool DNA Test

Frequency of testing: The current recommendation is once every three years. If positive on any of the occasions, endoscopic studies such as colonoscopy and sigmoidoscopy are recommended.[1] 

3.) Sigmoidoscopy

Screening frequency: Sigmoidoscopy should be performed at five-year intervals from baseline intervention, with gFOBT/FIT every three years.[1][24] 

3.) Colonoscopy

Screening frequency: Patients undergoing colonoscopy should have a 10-year interval between screening colonoscopies if the examination is negative and of adequate quality.[1][36]

4.) Computed Tomography Colonography

Screening frequency: Current USPSTF recommends CTC every five years from baseline CTC or optical colonoscopy. 

Details

Author

Rahul Kumar

Editor:

Catherine R. Lewis

Updated:

9/26/2022 7:39:23 PM

Feedback:

Send Us Your Comments

References

[1]

US Preventive Services Task Force, Bibbins-Domingo K, Grossman DC, Curry SJ, Davidson KW, Epling JW Jr, García FAR, Gillman MW, Harper DM, Kemper AR, Krist AH, Kurth AE, Landefeld CS, Mangione CM, Owens DK, Phillips WR, Phipps MG, Pignone MP, Siu AL. Screening for Colorectal Cancer: US Preventive Services Task Force Recommendation Statement. JAMA. 2016 Jun 21:315(23):2564-2575. doi: 10.1001/jama.2016.5989. Epub     [PubMed PMID: 27304597]

[2]

Issa IA,Noureddine M, Colorectal cancer screening: An updated review of the available options. World journal of gastroenterology. 2017 Jul 28     [PubMed PMID: 28811705]

[3]

Bailey CE,Hu CY,You YN,Bednarski BK,Rodriguez-Bigas MA,Skibber JM,Cantor SB,Chang GJ, Increasing disparities in the age-related incidences of colon and rectal cancers in the United States, 1975-2010. JAMA surgery. 2015 Jan;     [PubMed PMID: 25372703]

[4]

Troisi RJ,Freedman AN,Devesa SS, Incidence of colorectal carcinoma in the U.S.: an update of trends by gender, race, age, subsite, and stage, 1975-1994. Cancer. 1999 Apr 15;     [PubMed PMID: 10223559]

[5]

Jessup JM,McGinnis LS,Steele GD Jr,Menck HR,Winchester DP, The National Cancer Data Base. Report on colon cancer. Cancer. 1996 Aug 15     [PubMed PMID: 8756390]

[6]

Thörn M,Bergström R,Kressner U,Sparén P,Zack M,Ekbom A, Trends in colorectal cancer incidence in Sweden 1959-93 by gender, localization, time period, and birth cohort. Cancer causes     [PubMed PMID: 9578291]

[7]

Doubeni CA,Corley DA,Quinn VP,Jensen CD,Zauber AG,Goodman M,Johnson JR,Mehta SJ,Becerra TA,Zhao WK,Schottinger J,Doria-Rose VP,Levin TR,Weiss NS,Fletcher RH, Effectiveness of screening colonoscopy in reducing the risk of death from right and left colon cancer: a large community-based study. Gut. 2018 Feb;     [PubMed PMID: 27733426]

[8]

Yurgelun MB,Kulke MH,Fuchs CS,Allen BA,Uno H,Hornick JL,Ukaegbu CI,Brais LK,McNamara PG,Mayer RJ,Schrag D,Meyerhardt JA,Ng K,Kidd J,Singh N,Hartman AR,Wenstrup RJ,Syngal S, Cancer Susceptibility Gene Mutations in Individuals With Colorectal Cancer. Journal of clinical oncology : official journal of the American Society of Clinical Oncology. 2017 Apr 1;     [PubMed PMID: 28135145]

[9]

Davis DM,Marcet JE,Frattini JC,Prather AD,Mateka JJ,Nfonsam VN, Is it time to lower the recommended screening age for colorectal cancer? Journal of the American College of Surgeons. 2011 Sep;     [PubMed PMID: 21737316]

[10]

Ziogas A,Horick NK,Kinney AY,Lowery JT,Domchek SM,Isaacs C,Griffin CA,Moorman PG,Edwards KL,Hill DA,Berg JS,Tomlinson GE,Anton-Culver H,Strong LC,Kasten CH,Finkelstein DM,Plon SE, Clinically relevant changes in family history of cancer over time. JAMA. 2011 Jul 13;     [PubMed PMID: 21750294]

[11]

Yamada A,Komaki Y,Komaki F,Micic D,Zullow S,Sakuraba A, Risk of gastrointestinal cancers in patients with cystic fibrosis: a systematic review and meta-analysis. The Lancet. Oncology. 2018 Jun;     [PubMed PMID: 29706374]

Level 1 (high-level) evidence

[12]

Yuhara H,Steinmaus C,Cohen SE,Corley DA,Tei Y,Buffler PA, Is diabetes mellitus an independent risk factor for colon cancer and rectal cancer? The American journal of gastroenterology. 2011 Nov     [PubMed PMID: 21912438]

[13]

Machalek DA,Poynten M,Jin F,Fairley CK,Farnsworth A,Garland SM,Hillman RJ,Petoumenos K,Roberts J,Tabrizi SN,Templeton DJ,Grulich AE, Anal human papillomavirus infection and associated neoplastic lesions in men who have sex with men: a systematic review and meta-analysis. The Lancet. Oncology. 2012 May;     [PubMed PMID: 22445259]

Level 1 (high-level) evidence

[14]

Rabeneck L,Paszat LF,Hilsden RJ,Saskin R,Leddin D,Grunfeld E,Wai E,Goldwasser M,Sutradhar R,Stukel TA, Bleeding and perforation after outpatient colonoscopy and their risk factors in usual clinical practice. Gastroenterology. 2008 Dec;     [PubMed PMID: 18938166]

[15]

Robertson DJ,Lee JK,Boland CR,Dominitz JA,Giardiello FM,Johnson DA,Kaltenbach T,Lieberman D,Levin TR,Rex DK, Recommendations on Fecal Immunochemical Testing to Screen for Colorectal Neoplasia: A Consensus Statement by the US Multi-Society Task Force on Colorectal Cancer. Gastroenterology. 2017 Apr;     [PubMed PMID: 27769517]

Level 3 (low-level) evidence

[16]

Collins JF,Lieberman DA,Durbin TE,Weiss DG, Accuracy of screening for fecal occult blood on a single stool sample obtained by digital rectal examination: a comparison with recommended sampling practice. Annals of internal medicine. 2005 Jan 18;     [PubMed PMID: 15657155]

[17]

Robertson DJ,Lee JK,Boland CR,Dominitz JA,Giardiello FM,Johnson DA,Kaltenbach T,Lieberman D,Levin TR,Rex DK, Recommendations on fecal immunochemical testing to screen for colorectal neoplasia: a consensus statement by the US Multi-Society Task Force on colorectal cancer. Gastrointestinal endoscopy. 2017 Jan;     [PubMed PMID: 27769516]

Level 3 (low-level) evidence

[18]

Imperiale TF,Ransohoff DF,Itzkowitz SH,Turnbull BA,Ross ME, Fecal DNA versus fecal occult blood for colorectal-cancer screening in an average-risk population. The New England journal of medicine. 2004 Dec 23;     [PubMed PMID: 15616205]

[19]

Ouyang DL,Chen JJ,Getzenberg RH,Schoen RE, Noninvasive testing for colorectal cancer: a review. The American journal of gastroenterology. 2005 Jun     [PubMed PMID: 15929776]

[20]

Elmunzer BJ,Hayward RA,Schoenfeld PS,Saini SD,Deshpande A,Waljee AK, Effect of flexible sigmoidoscopy-based screening on incidence and mortality of colorectal cancer: a systematic review and meta-analysis of randomized controlled trials. PLoS medicine. 2012     [PubMed PMID: 23226108]

Level 1 (high-level) evidence

[21]

Schoen RE,Pinsky PF,Weissfeld JL,Yokochi LA,Church T,Laiyemo AO,Bresalier R,Andriole GL,Buys SS,Crawford ED,Fouad MN,Isaacs C,Johnson CC,Reding DJ,O'Brien B,Carrick DM,Wright P,Riley TL,Purdue MP,Izmirlian G,Kramer BS,Miller AB,Gohagan JK,Prorok PC,Berg CD, Colorectal-cancer incidence and mortality with screening flexible sigmoidoscopy. The New England journal of medicine. 2012 Jun 21;     [PubMed PMID: 22612596]

[22]

Atkin WS,Edwards R,Kralj-Hans I,Wooldrage K,Hart AR,Northover JM,Parkin DM,Wardle J,Duffy SW,Cuzick J, Once-only flexible sigmoidoscopy screening in prevention of colorectal cancer: a multicentre randomised controlled trial. Lancet (London, England). 2010 May 8;     [PubMed PMID: 20430429]

Level 1 (high-level) evidence

[23]

Lin JS,Piper MA,Perdue LA,Rutter CM,Webber EM,O'Connor E,Smith N,Whitlock EP, Screening for Colorectal Cancer: Updated Evidence Report and Systematic Review for the US Preventive Services Task Force. JAMA. 2016 Jun 21;     [PubMed PMID: 27305422]

Level 1 (high-level) evidence

[24]

Brenner H,Stock C,Hoffmeister M, Effect of screening sigmoidoscopy and screening colonoscopy on colorectal cancer incidence and mortality: systematic review and meta-analysis of randomised controlled trials and observational studies. BMJ (Clinical research ed.). 2014 Apr 9     [PubMed PMID: 24922745]

Level 1 (high-level) evidence

[25]

van Rijn JC,Reitsma JB,Stoker J,Bossuyt PM,van Deventer SJ,Dekker E, Polyp miss rate determined by tandem colonoscopy: a systematic review. The American journal of gastroenterology. 2006 Feb     [PubMed PMID: 16454841]

Level 1 (high-level) evidence

[26]

Pickhardt PJ,Nugent PA,Mysliwiec PA,Choi JR,Schindler WR, Location of adenomas missed by optical colonoscopy. Annals of internal medicine. 2004 Sep 7;     [PubMed PMID: 15353426]

[27]

Rex DK,Adler SN,Aisenberg J,Burch WC Jr,Carretero C,Chowers Y,Fein SA,Fern SE,Fernandez-Urien Sainz I,Fich A,Gal E,Horlander JC Sr,Isaacs KL,Kariv R,Lahat A,Leung WK,Malik PR,Morgan D,Papageorgiou N,Romeo DP,Shah SS,Waterman M, Accuracy of capsule colonoscopy in detecting colorectal polyps in a screening population. Gastroenterology. 2015 May;     [PubMed PMID: 25620668]

[28]

Zalis ME,Blake MA,Cai W,Hahn PF,Halpern EF,Kazam IG,Keroack M,Magee C,Näppi JJ,Perez-Johnston R,Saltzman JR,Vij A,Yee J,Yoshida H, Diagnostic accuracy of laxative-free computed tomographic colonography for detection of adenomatous polyps in asymptomatic adults: a prospective evaluation. Annals of internal medicine. 2012 May 15;     [PubMed PMID: 22586008]

[29]

Iannaccone R,Laghi A,Catalano C,Mangiapane F,Lamazza A,Schillaci A,Sinibaldi G,Murakami T,Sammartino P,Hori M,Piacentini F,Nofroni I,Stipa V,Passariello R, Computed tomographic colonography without cathartic preparation for the detection of colorectal polyps. Gastroenterology. 2004 Nov;     [PubMed PMID: 15520999]

[30]

Johnson DA,Barclay RL,Mergener K,Weiss G,König T,Beck J,Potter NT, Plasma Septin9 versus fecal immunochemical testing for colorectal cancer screening: a prospective multicenter study. PloS one. 2014     [PubMed PMID: 24901436]

Level 2 (mid-level) evidence

[31]

Jin P,Kang Q,Wang X,Yang L,Yu Y,Li N,He YQ,Han X,Hang J,Zhang J,Song L,Han Y,Sheng JQ, Performance of a second-generation methylated SEPT9 test in detecting colorectal neoplasm. Journal of gastroenterology and hepatology. 2015 May     [PubMed PMID: 25471329]

[32]

van Rossum LG,van Rijn AF,van Oijen MG,Fockens P,Laheij RJ,Verbeek AL,Jansen JB,Dekker E, False negative fecal occult blood tests due to delayed sample return in colorectal cancer screening. International journal of cancer. 2009 Aug 15     [PubMed PMID: 19408302]

[33]

Duffy MJ,van Rossum LG,van Turenhout ST,Malminiemi O,Sturgeon C,Lamerz R,Nicolini A,Haglund C,Holubec L,Fraser CG,Halloran SP, Use of faecal markers in screening for colorectal neoplasia: a European group on tumor markers position paper. International journal of cancer. 2011 Jan 1     [PubMed PMID: 20824704]

[34]

Hol L,van Leerdam ME,van Ballegooijen M,van Vuuren AJ,van Dekken H,Reijerink JC,van der Togt AC,Habbema JD,Kuipers EJ, Screening for colorectal cancer: randomised trial comparing guaiac-based and immunochemical faecal occult blood testing and flexible sigmoidoscopy. Gut. 2010 Jan;     [PubMed PMID: 19671542]

Level 1 (high-level) evidence

[35]

Zapka J,Klabunde CN,Taplin S,Yuan G,Ransohoff D,Kobrin S, Screening colonoscopy in the US: attitudes and practices of primary care physicians. Journal of general internal medicine. 2012 Sep     [PubMed PMID: 22539065]

[36]

Singh H,Turner D,Xue L,Targownik LE,Bernstein CN, Risk of developing colorectal cancer following a negative colonoscopy examination: evidence for a 10-year interval between colonoscopies. JAMA. 2006 May 24;     [PubMed PMID: 16720822]