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Overview of colonoscopy in adults

Overview of colonoscopy in adults
Authors:
Linda Lee, MD
John R Saltzman, MD, FACP, FACG, FASGE, AGAF
Section Editor:
Douglas A Howell, MD, FASGE, FACG
Deputy Editor:
Shilpa Grover, MD, MPH, AGAF
Literature review current through: Dec 2022. | This topic last updated: Apr 21, 2021.

INTRODUCTION — Colonoscopy is used both diagnostically and therapeutically and permits examination and treatment of the rectum, colon, and a portion of the terminal ileum. Performance of a high-quality colonoscopy examination requires understanding and mastery of cognitive and technical skills. A joint American Society of Gastrointestinal Endoscopy/American College of Gastroenterology Taskforce on Quality in Endoscopy advocated the following quality indicators before, during, and after colonoscopy [1,2] (see 'Quality indicators' below):

Preprocedure – Attention must be paid to the general issues of timely scheduling, appropriate patient preparation, targeted history and physical examination, evaluation of bleeding risk, assessment for appropriate sedation, and team pause before commencing sedation. It is also important to understand appropriate indications and recommended surveillance intervals based upon the patient's risk factors (eg, family history of colorectal cancer, prior adenomatous polyps, hereditary colon cancer syndrome, or inflammatory bowel disease). Finally, obtaining informed consent with a detailed explanation of the risks associated with colonoscopy is essential.

Intraprocedure – Performing a high-quality examination requires careful visualization of the entire colonic mucosa. Metrics such as cecal intubation rates, withdrawal times, and adenoma detection rates serve as surrogate, though imperfect, markers of careful visualization. In addition, a high-quality examination requires appropriate tissue acquisition (eg, surveillance biopsies in inflammatory bowel disease) and endoscopic removal of all polyps less than 2 cm. Removal of polyps larger than 2 cm may require special endoscopic skills.

Postprocedure – There must be immediate, complete, and accurate documentation (both written and photographic) of preparation quality and findings, as well as explicit recommendations for follow-up. Tissue samples taken during colonoscopy must be documented. Pathology results should be reviewed with results and recommendations communicated to the patient and referring providers. Finally, there should be a system for tracking complications.

This topic will review factors associated with performing a colonoscopy including indications, patient preparation, technical aspects, and complications. Issues related to colon cancer screening recommendations, bowel preparations for colonoscopy, procedural sedation, and the management of antiplatelet or anticoagulant medications in patients undergoing endoscopy, and special considerations for colonoscopy in the setting of the COVID-19 pandemic are discussed separately. (See "Screening for colorectal cancer: Strategies in patients at average risk" and "Screening for colorectal cancer in patients with a family history of colorectal cancer or advanced polyp" and "Overview of colon polyps" and "Bowel preparation before colonoscopy in adults" and "Gastrointestinal endoscopy in adults: Procedural sedation administered by endoscopists" and "Management of antiplatelet agents in patients undergoing endoscopic procedures" and "Management of anticoagulants in patients undergoing endoscopic procedures" and "COVID-19: Issues related to gastrointestinal disease in adults", section on 'Implications for endoscopy'.)

PATIENT SELECTION — Patient selection for colonoscopy focuses on the indication for the procedure and patient comorbidities to enable proper risk stratification.

The American Society of Gastrointestinal Endoscopy has outlined general principles for the appropriate use of endoscopy [3]. Endoscopy may be appropriate if any of the following criteria are fulfilled:

The results are likely to change the patient's management

Empiric treatment of a benign disease has failed

A therapeutic intervention is anticipated

It is being used as an alternative to radiologic evaluation

On the other hand, endoscopy is not indicated when the results are not expected to impact management or for the follow-up of benign diseases that have healed, unless surveillance of a premalignant condition is appropriate.

Indications — Colonoscopy is performed for both diagnostic and therapeutic indications (table 1) [2]. Diagnostic indications include screening or surveillance for colon cancer, evaluating signs and symptoms suggestive of possible colonic or distal small bowel disease, assessing a response to treatment in patients with known colonic disease (eg, inflammatory bowel disease), and evaluating abnormalities found on imaging studies. Therapeutic indications include stricture dilation, stent placement, colonic decompression, and foreign body removal. In addition, lesions found during diagnostic procedures may require therapeutic intervention (eg, polypectomy or treatment of a bleeding lesion). (See 'Diagnostic and therapeutic maneuvers' below.)

Screening or surveillance for colon cancer – Colonoscopy is considered the gold standard for colon cancer screening and surveillance. The age at which screening starts will depend upon the patient's medical and family history. If polyps are found during colonoscopy, they should be removed endoscopically if possible. (See "Screening for colorectal cancer: Strategies in patients at average risk" and "Screening for colorectal cancer in patients with a family history of colorectal cancer or advanced polyp" and "Surveillance and management of dysplasia in patients with inflammatory bowel disease" and 'Polypectomy' below.)

The interval for repeat screening or surveillance will again depend upon the patient's medical and family history, as well as the findings on prior colonoscopies. (See "Overview of colon polyps" and "Post-treatment surveillance after colorectal cancer treatment".)

Lower gastrointestinal bleeding – Patients with active or recent hematochezia, positive fecal occult blood, or melena after an upper gastrointestinal source has been excluded should undergo colonoscopy for diagnosis and, if a source of bleeding is identified, potentially endoscopic therapy. In addition, unexplained iron deficiency anemia should be evaluated with colonoscopy, as colon cancer is an important cause of iron deficiency anemia in adults. (See "Approach to acute lower gastrointestinal bleeding in adults" and "Causes and diagnosis of iron deficiency and iron deficiency anemia in adults", section on 'Search for source of blood and iron loss'.)

Lower gastrointestinal symptoms – Colonoscopy should be performed in patients with chronic, clinically significant diarrhea without an explanation. Random colon biopsies should be obtained throughout the colon to rule out microscopic colitis. Colonoscopy is generally not indicated as part of the evaluation for chronic constipation unless warning signs are present (eg, anemia, weight loss) or the patient has not undergone recommended screening or surveillance. Whether to perform a colonoscopy in a patient with chronic abdominal pain will depend upon patient risk factors (eg, age >50 years), the character and location of the pain, and associated signs and symptoms. (See "Etiology and evaluation of chronic constipation in adults", section on 'Endoscopy' and "Evaluation of the adult with abdominal pain".)

Abnormal imaging – Colonoscopy is indicated to evaluate abnormalities detected on barium enema, abdominal computed tomography (CT), positron emission tomography CT, magnetic resonance imaging, or other imaging studies. Radiographic findings requiring colonoscopic evaluation include thickening of the wall of the colon or terminal ileum (image 1), mass lesions (figure 1), filling defects (image 2 and image 3), and strictures (image 4). In addition, colonoscopy may be indicated in patients with metastatic adenocarcinoma of unknown primary or who are found to have polyps on CT colonography (virtual colonoscopy), depending upon the size of the polyp (picture 1). (See "Overview of computed tomographic colonography", section on 'Indications' and "Overview of the classification and management of cancers of unknown primary site", section on 'Adenocarcinoma'.)

Evaluation for synchronous or metachronous cancer in patients with colon cancer – Patients with colon cancer are at risk for synchronous cancer. As a result, patients with colon cancer require a complete examination of the colon. Ideally, this is done prior to surgery, though in some patients complete preoperative colonoscopy will not be possible (eg, due to inability to pass the colonoscope beyond an obstructing tumor). Such patients require colonoscopy soon after resection of the primary tumor. (See "Post-treatment surveillance after colorectal cancer treatment", section on 'Perioperative colonoscopy'.)

Following treatment of the primary tumor, patients require routine surveillance to look for new polyps or metachronous cancer. Several expert groups have made recommendations regarding the timing and frequency of posttreatment endoscopic surveillance. (See "Post-treatment surveillance after colorectal cancer treatment", section on 'Postoperative endoscopic surveillance' and "Post-treatment surveillance after colorectal cancer treatment", section on 'Guidelines from major groups'.)

Intraoperative lesion localization – Colonoscopy may be performed intraoperatively to identify a lesion identified on imaging or prior colonoscopy that is not apparent at surgery, such as a bleeding site or small mass. For lesions previously identified with colonoscopy, intraoperative colonoscopy can often be avoided if the area with the lesion is marked during the colonoscopy (picture 2A-C). In such cases, lesions are typically tattooed a few centimeters distal to the lesion. Exactly where the tattoo was performed in relationship to the lesion must be clearly documented and communicated to the surgeon. (See "Tattooing and other methods for localizing gastrointestinal lesions".)

Inflammatory bowel disease – Colonoscopy is often performed in patients with inflammatory bowel disease to assess the extent and/or severity of disease and to assess treatment responses. In addition, patients with colitis require routine surveillance for colonic dysplasia. (See "Endoscopic diagnosis of inflammatory bowel disease in adults" and "Surveillance and management of dysplasia in patients with inflammatory bowel disease".)

Evaluation of the terminal ileum – In patients with suspected disease involving the distal small bowel, such as Crohn disease, carcinoid, and bleeding, colonoscopy can be used to evaluate the terminal ileum.

Therapeutic indications – Therapeutic indications for colonoscopy include foreign body removal, decompression of sigmoid volvulus or colonic pseudoobstruction, balloon dilation of strictures, palliative treatment of bleeding or stenosed neoplasms, and percutaneous endoscopic cecostomy tube placement. (See "Rectal foreign bodies" and "Sigmoid volvulus" and "Acute colonic pseudo-obstruction (Ogilvie's syndrome)" and "Management of anastomotic complications of colorectal surgery" and "Enteral stents for the management of malignant colorectal obstruction".)

Contraindications — Colonoscopy is contraindicated in the following situations:

When the risks of the colonoscopy outweigh the expected benefits

Consent cannot be obtained for a non-urgent procedure

A perforation is known or suspected

Documented acute diverticulitis

Fulminant colitis

It is important that the expected benefits of colonoscopy be carefully weighed against the risks, particularly in older adults and patients with comorbid illnesses because these patients are at increased risk for serious complications from colonoscopy. (See 'Complications' below.)

If a patient cannot be adequately sedated despite a reasonable attempt at sedation, colonoscopy should be delayed until adequate sedation can be provided (eg, monitored anesthesia care or general anesthesia). Finally, a suspected poor preparation is a relative contraindication to colonoscopy. (See 'Patient preparation' below and "Gastrointestinal endoscopy in adults: Procedural sedation administered by endoscopists".)

Important considerations — Before the procedure, patients should be evaluated for factors that may affect the ability to perform a colonoscopy safely and successfully, including:

Anatomic issues, such as recent colonic surgery, history of abdominal and/or pelvic surgeries, abdominal hernias, and presence of a colostomy

Comorbidities that may increase the risks associated with sedation (see "Gastrointestinal endoscopy in adults: Procedural sedation administered by endoscopists", section on 'Presedation evaluation')

Comorbidities that may impact the ability of an assistant to apply abdominal pressure and/or position the patient during colonoscopy

Presence of an implanted cardiac defibrillator and some pacemakers that may require special management during application of electrocautery

Chronic use of medications such as benzodiazepines or narcotics that may increase a patient's tolerance to the effects of sedation

A history of difficult intubation by anesthesia

PATIENT PREPARATION

Diet — Patients need to consume a low-residue diet or clear liquids for at least one day prior to elective colonoscopy. A low-residue diet is low in fiber, and patients should be instructed to avoid foods that are high in fiber such as fruits, vegetables, and whole grains (table 2). Clear liquids include water, clear broth, coffee or tea (without milk), ices, gelatin, and fruit juices such as apple, grapefruit, and lemonade. Liquids that are red can be mistaken for blood in the colon or can obscure mucosal details and should be avoided. One trial found that there was no significant difference in preparation quality between patients treated with 4L of polyethylene glycol who were assigned to receive either a low-residue diet or clear liquids the day prior to the examination [4]. Similarly, a randomized trial with 230 patients who were receiving a sodium sulfate-based preparation assigned patients to either a low-residue diet for breakfast and lunch the day prior to the colonoscopy or to clear liquids [5]. Again, there was no difference between the groups with regard to preparation quality. However, patients in the low-residue arm reported greater satisfaction with the preparation and were less likely to cancel their procedure (9 versus 20 percent). Whether similar results would be seen outside of a randomized trial is not yet known. Our approach is to recommend a low-residue diet for five days prior to colonoscopy, with only clear liquids allowed the day prior to the examination.

Patients typically take no food by mouth for four to eight hours prior to the procedure (sometimes longer if there is known or suspected delayed gastric emptying) and no liquids (other than sips with medications) for two hours [6]. Recommendations differ with regard to preprocedure fasting for elective procedures. The American Society for Anesthesiology (ASA) guidelines state that prior to a procedure, patients should fast a minimum of two hours following clear liquid ingestion or six hours for a light meal [7]. By contrast, the American College of Emergency Physicians states "recent food intake is not a contraindication for administering procedural sedation and analgesia, but should be considered in choosing the timing and target level of sedation" [8]. Our practice is to follow the ASA approach.

Medications — Most medications may be continued up to the time of colonoscopy and are taken with a small sip of water the day of the colonoscopy. Some medications may need to be adjusted prior to colonoscopy, such as medications for diabetes, due to decreased oral intake prior to the procedure. Oral iron should also be stopped at least five days before the colonoscopy since it makes the residual feces black, viscous, and difficult to purge.

Decisions regarding the management of antiplatelet agents or anticoagulants must weigh the risks of bleeding from the procedure with the probability of a thromboembolic event occurring while the antithrombotic medication is interrupted (table 3 and table 4) [9]. Furthermore, the urgency of the procedure and the availability of alternative tests must be evaluated. Management decisions about antithrombotic agents should be made following discussion with the patient and the clinician prescribing the medication. Aspirin and nonsteroidal antiinflammatory drugs in standard doses may be continued safely in patients having colonoscopy. (See "Management of anticoagulants in patients undergoing endoscopic procedures" and "Management of antiplatelet agents in patients undergoing endoscopic procedures" and "Gastrointestinal endoscopy in patients with disorders of hemostasis".)

Because the risk of infection related to routine diagnostic or therapeutic colonoscopy is low, antibiotic prophylaxis is not recommended for colonoscopy (table 5). (See "Antibiotic prophylaxis for gastrointestinal endoscopic procedures".)

Preprocedure testing — It is generally recommended that patients not undergo routine preprocedure laboratory testing, chest radiography, or electrocardiography [10]. Instead, preprocedure testing should be used selectively based on the patient's medical history, physical examination findings, and procedural risk factors.

We agree with 2014 guidelines from the American Society for Gastrointestinal Endoscopy that recommend preprocedure testing in the following settings [10]:

Pregnancy testing for women of childbearing potential who provide an uncertain pregnancy history or who have a history suggestive of a current pregnancy (particularly if fluoroscopy is going to be used).

Coagulation studies for patients with active bleeding, a known or suspected bleeding disorder (including a history of abnormal bleeding), an increased risk of bleeding due to medication use (eg, ongoing anticoagulant use, prolonged antibiotic use), prolonged biliary obstruction, malnutrition, or other conditions associated with acquired coagulopathies.

Chest radiograph for patients with new respiratory symptoms or decompensated heart failure.

Hemoglobin/hematocrit for patients with preexisting significant anemia or active bleeding, or if there is a high risk of significant blood loss during the procedure.

Blood typing for patients with active bleeding or anemia who are likely to need a blood transfusion.

Serum chemistry testing for patients with significant endocrine, renal, or hepatic dysfunction if medications are to be used that may further impair function.

We do not routinely check coagulation studies for patients who are receiving anticoagulants if the medication has been held for an appropriate amount of time prior to the procedure. (See "Management of anticoagulants in patients undergoing endoscopic procedures", section on 'High or uncertain risk procedures'.)

Bowel preparation — An excellent bowel preparation is critical for colonoscopy because it permits visualization of the entire colonic mucosa and increases the safety of therapeutic maneuvers [11,12]. However, inadequate or poor preparation occurs in approximately 20 to 25 percent of colonoscopies in the United States [13]. Poor preparation leads to increased procedure time, risk of complications, and probability of missing lesions [14]. Multiple bowel preparations exist, with the ideal preparation being effective, safe, and palatable. It is important to consider the patient's comorbid illnesses and the timing of the preparation when choosing an appropriate preparation or combination of preparations. (See "Bowel preparation before colonoscopy in adults".)

Bowel preparations are often described with terms such as unsatisfactory/inadequate, poor, fair, good, and excellent. To standardize descriptions, systems for reporting bowel preparation quality have been developed, including the Boston bowel preparation scale [15]. The score ranges from 0 to 3 (picture 3) for individual colonic segments: the right side of the colon (including the cecum and ascending colon), the transverse section of the colon (including the hepatic and splenic flexures), and the left side of the colon (including the descending colon, sigmoid colon, and rectum). These segment scores are summed for a total Boston bowel preparation scale score, which ranges from 0 (poor) to 9 (excellent):

Score 0: Unprepared colon with mucosa not seen because of solid stool that cannot be cleared

Score 1: Portion of the mucosa of the colon segment seen, but other areas of the colon segment not seen well because of staining, residual stool, and/or opaque liquid

Score 2: Minor amount of residual staining, small fragments of stool and/or opaque liquid, but most mucosa of the colon segment seen well

Score 3: Entire mucosa of colon segment seen well with no residual staining, small fragments of stool, and/or opaque liquid

SEDATION ASSESSMENT — Options for sedation for colonoscopy include no sedation, moderate procedural sedation, or deep sedation. Deciding upon the appropriate approach requires an assessment of the patient's sedation needs and risks prior to the colonoscopy [16,17]. This includes a complete history of factors that might make sedation more difficult such as prior difficulties with sedation, chronic narcotic or benzodiazepine use, diminished mental capacity, and agitation or severe anxiety. Special attention should be paid to whether the patient has an increased risk for difficult airway management (eg, obesity, non-visibility of the uvula, prior history of difficult intubation) or increased cardiopulmonary complications of endoscopy (eg, comorbidities, obesity, older age). (See "Gastrointestinal endoscopy in adults: Procedural sedation administered by endoscopists".)

Although deep sedation with propofol is associated with greater patient satisfaction, faster post-procedure recovery time, and in some studies shorter procedure time, it does not lead to improvements in other clinically important outcomes such as cecal intubation rates or adenoma detection rates [18,19]. Use of anesthesia during colonoscopy may be associated with increased complications, including perforation following polypectomy, bleeding, abdominal pain, and complications associated with anesthesia [20]. Furthermore, when administered by an anesthesiologist or dedicated nurse, deep sedation substantially increases the total cost of the procedure [21]. It is important to note that in some cases the additional costs associated with the administration of deep sedation may not be covered by a patient's health insurance. (See "Gastrointestinal endoscopy in adults: Procedural sedation administered by endoscopists".)

INFORMED CONSENT — Informed consent is a process, not merely a form, and it encompasses all the interactions between the healthcare provider and the patient. Informed consent includes full disclosure with a clear and complete explanation of all portions of the procedure. (See "Informed procedural consent".)

Five essential elements to discuss in preparation for any procedure include [22]:

Nature of the procedure

Benefits

Risks

Alternatives

Limitations of the procedure

The use of clear and simple language is critical during the process of obtaining consent. For example, colonoscopy may be explained as "a procedure in which a doctor passes a flexible tube with a light and a camera through your anus into your colon." Discussion of the possible risks of colonoscopy, including frequent and less frequent but severe complications, must occur and be tailored to the specific patient and procedure. Incidences of possible complications should be mentioned. (See 'Complications' below.)

Written documentation of the consent process is mandatory. In addition, when needed, the use of translators and materials written in a language in which the patient is fluent are also important.

EQUIPMENT — Routine colonoscopy is performed using a high-definition white-light colonoscope. Both adult and pediatric colonoscopes are used for colonoscopy in adults (with pediatric colonoscopes often being used for women or patients with a history of abdominal surgery). The choice of colonoscope does not affect cecal intubation rates or times [23]. Adult colonoscopes have a diameter of approximately 13 mm, whereas pediatric colonoscopes have a diameter of approximately 11 mm. Use of a pediatric colonoscope may enable easier passage through narrowed or fixed areas of the colon. However, the smaller diameter makes the pediatric colonoscope more flexible, which predisposes to loop formation. The choice of an adult versus pediatric colonoscope is typically a matter of endoscopist preference. Occasionally the endoscopist may need to change from one type of colonoscope to the other to facilitate completion of the colonoscopy (see 'Looping' below). An ultra-slim colonoscope with a diameter of 9.5 mm may be particularly helpful in patients with tight turns.

Variable stiffness colonoscopes allow the endoscopist to stiffen the shaft of the colonoscope and appear to increase cecal intubation rates [24]. Often the colonoscope is stiffened after passage through the sigmoid colon to reduce loop formation. The colonoscope is typically loosened during withdrawal, retroflexion, or passage around tight turns.

Various accessories are available that can be passed through the accessory channel of a colonoscope. These include biopsy forceps, brushes, snares, baskets, nets, injection needles, hemostatic clips, and argon plasma coagulation probes.

COLONOSCOPE ADVANCEMENT AND MUCOSAL INSPECTION — Colonoscopy routinely begins with the patient in the left lateral decubitus position, with the exception of patients with a colostomy, who typically remain supine. The first step is inspection of the perianal region and digital rectal examination. Topical anesthetic lubricating gel should be used for patients with perianal discomfort, whereas standard lubricant can be used for patients without discomfort. The tip of the colonoscope is then inserted into the rectum with air insufflation, suctioning of residual fluid, and pulling back of the colonoscope to enable visualization. The rectosigmoid junction is at approximately 15 to 20 cm, at which point the colon enters the peritoneum. Particular care must be taken when advancing the colonoscope in patients with colonic strictures or significant diverticulosis, as air insufflation can increase the risk of perforation in such patients. (See 'Perforation' below.)

Important techniques used during colonoscopy include using the up-down and left-right knobs and aspirating air. Using the knobs is particularly helpful in negotiating turns. Although gentle air insufflation helps visualization as the colonoscope is advanced, filling the colon with air lengthens and distends the colon, which may cause discomfort and increase the difficulty of the procedure. Aspirating the air will deflate and shorten the colon, bringing the next fold closer to the tip of the colonoscope, reducing abdominal discomfort and often aiding with scope advancement. The use of carbon dioxide instead of air to insufflate may reduce distension and patient discomfort as well [25]. Although limited data suggest that carbon dioxide insufflation in patients with underlying pulmonary disease is not associated with an increased risk of respiratory depression or carbon dioxide retention, additional studies are needed [25-27].

Distending the lumen of the colon with water may facilitate advancement of the colonoscope with decreased pain [28-30]. This technique may be especially helpful when navigating a left colon filled with numerous diverticula that make it difficult to identify the colonic lumen. Studies support decreased sedation requirements and improved patient tolerance with the use of water rather than air insufflation; however, other studies suggest decreased adenoma detection rates [29,31-33]. In a meta-analysis with 16 randomized trials that compared insufflation with water and insufflation with air, insufflation with water was associated with less pain (-1.57 point difference in pain score on a 0 to 10 scale, 95% CI -2.00 to -1.14), a higher likelihood of being able to complete the examination without sedation or analgesia (risk ratio [RR] 1.20, 95% CI 1.14 to 1.27), and higher adenoma detection rates (RR 1.16, 95% CI 1.04 to 1.30) [30]. There was no difference in cecal intubation rate.

Intubating the terminal ileum can be performed with two different approaches. The colonoscope may be advanced through the opening of the valve by direct visualization during forward movement. Alternatively, the colonoscope may be positioned in the cecum near the appendiceal orifice and slowly withdrawn, with the tip of the colonoscope angled toward the direction of the valve opening in an attempt to "hook" the valve.

Looping — A major barrier to successful advancement of the colonoscope to the cecum is looping. Looping occurs due to the attachment of the sigmoid and transverse colon to a mobile mesentery (figure 2). Advancing the colonoscope becomes more difficult, and in some cases, attempts to advance the colonoscope result in reverse movement of the colonoscope tip, termed paradoxical movement. In addition to impeding advancement of the colonoscope, looping can cause pain and perforation. Pain occurs due to the presence of sensory receptors in the mesentery responding to torsion, distension, compression, and stretching. Repeated loop reduction during the colonoscopy is critical and requires pulling back the colonoscope while applying torque, often clockwise. Stopping any maneuver if it causes significant pain, pressure, or difficulty is important to decrease the risk of complications. Loops formed in the instrument shaft outside the patient should be removed by rotating the colonoscope, keeping the lumen in view.

Applying abdominal pressure and changing the patient's position are important adjunctive techniques to enable passage of the colonoscope to the cecum. Abdominal pressure was the most important non-instrumental factor for cecal intubation in patients referred for incomplete colonoscopy [34]. Loops should be removed before the assistant applies pressure to help prevent loop further formation.

Asking the patient to demonstrate the location of abdominal discomfort may also help identify the appropriate area to apply pressure. In addition, abdominal pressure should be applied to abdominal hernias. In such patients, loops that form within the hernia may lead to entrapment of the colonoscope [35].

While not widely available, an alternative method for determining where to apply pressure is magnetic endoscopic imaging. Magnetic endoscopic imaging provides real-time three-dimensional views of the colonoscope shaft configuration and its location within the abdomen. This information can aid with loop reduction and can be used to identify where to provide external pressure. (See "Magnetic endoscopic imaging".)

Changing the patient's position also may aid advancement of the colonoscope. In addition to the standard left lateral position, patients may be positioned in a supine, right lateral, or prone position. One study demonstrated that position changes were effective two-thirds of the time in allowing forward advancement of the colonoscope or improved luminal visualization [36].

Inspection — Careful inspection of the colonic mucosa is primarily performed during withdrawal of the colonoscope. In addition to polyps (and tumors if present), the presence of erythema, erosions, ulcers, diverticula, melanosis coli, hemorrhoids, and condyloma should be noted. A withdrawal time of at least six minutes improves adenoma detection rates, but inspection technique appears to be as important as time spent inspecting [37,38]. The following techniques are important for ensuring optimal visualization:

Cleaning the colon of residual fluid during insertion and withdrawal. Residual stool may be aspirated into a plastic trap for microbiology analysis if needed.

Clearing bubbles with simethicone in the water flushes used during insertion and withdrawal.

Adequate insufflation during withdrawal.

Visualizing the entire circumference of the colon by moving the tip of colonoscope in a systematic "circular" pattern.

Inspecting behind and in between folds.

Repeated inspection of areas by back and forth movement of the colonoscope, especially around turns.

Reducing colonic contractions by cleaning during colonoscope advancement to minimize suctioning upon withdrawal. Antispasmodics may also be used, although studies have failed to demonstrate improved adenoma detection rates with their use [39].

Changing the patient's position during withdrawal has been shown to improve adenoma detection rates, with the following positions used based upon the location of the tip of the colonoscope: cecum to hepatic flexure, left lateral position; transverse colon, supine position; splenic flexure and descending colon, right lateral position [40].

Careful inspection of vascularity and areas with mucus since flat lesions may manifest only as subtle changes to the vascular pattern or may be obscured by adherent mucus.

Having experienced nurses and assistants examine the colonic mucosa simultaneously with the endoscopist has led to improved adenoma detection rates [41,42].

The endoscopist cannot always accurately identify the location of the colonoscope tip in the colon. Identifying position by the distances marked on the shaft of the colonoscope is not reliable due to looping, although approximately 60 to 80 cm of the instrument will typically be inserted upon reaching the cecum once loops have been removed. Only the terminal ileum (picture 4), cecum (picture 5), and rectum (picture 6) can be recognized 100 percent of the time by experienced endoscopists. The appendiceal orifice (picture 7) and ileocecal valve (picture 8) with two lipomatous lips identify the cecum. Care must be taken not to confuse the cecum with a tight turn or the appendiceal orifice with a diverticulum. The hepatic and splenic flexures may be identified by the bluish hue of adjacent organs (the liver and spleen, respectively) visualized through the colonic mucosa (picture 9). The transverse colon typically has a triangular fold configuration (picture 10).

Multiple options are available to enhance visualization during colonoscopy, though many require specialized equipment and training. These techniques include narrow band imaging, magnification endoscopy, chromoendoscopy, and confocal laser endomicroscopy. These techniques are not routinely used but may be employed in certain circumstances (eg, detecting dysplasia in patients with inflammatory bowel disease). These colonoscopes include imagers not only on the tip of the colonoscope, but also on the sides (providing a 330 degree angle of view). The scopes were shown in a randomized trial to decrease adenoma miss rates compared with standard forward-viewing colonoscopes (7 versus 41 percent) [43]. In a systematic review and network meta-analysis that compared the efficacy of different endoscopic techniques in increasing adenoma detection rates (ADR), low-cost measures optimizing of existing resources (water-aided colonoscopy, second observer, dynamic position change) were associated with a moderate increase in ADR compared with high-definition colonoscopy alone (odds ratio [OR], 1.29; 95% CI,1.17–1.43) [44]. Low-cost measures appeared to be as effective as enhanced imaging techniques (chromoendoscopy, narrow-band imaging, flexible spectral imaging color enhancement, blue laser imaging) (OR, 1.21; 95% CI, 1.09–1.35) and add-on devices (cap, endocuff, endo-rings, G-EYE) (OR, 1.18; 95% CI, 1.07–1.29), which also modestly increased ADR. However, the use of enhanced scopes (full-spectrum endoscopy, extra-wide-angle-view colonoscopy, dual focus) was not associated with significant increases in ADR during high-definition colonoscopy.

Studies suggest that the use of computer-aided diagnosis can assist in improving ADRs [45-51]. However, the efficacy of this technology has not been demonstrated in the detection of advanced adenomas. In a systematic review and meta-analysis of five randomized trials that included 4354 patients, colonoscopies performed with a computer-aided polyp detection system had higher pooled ADRs as compared with conventional colonoscopy [51]. Computer-aided polyp detection resulted in higher adenoma per colonoscopy regardless of size and polyp location. While computer-aided polyp detection also resulted in a higher sessile serrated lesion per colonoscopy (RR, 1.52; 95% CI, 1.14-2.02), rates of advanced ADR were not significantly different (RR, 1.35; 95% CI, 0.74-2.47). One such computer-aided detection system has been approved for use in the United States by the Food and Drug Administration [52]. However, further studies are also needed to determine if the use of computer-aided polyp diagnosis methods can consistently provide reliable and reproducible accuracy in the detection and characterization of colorectal polyps and improve long-term outcomes.  

DIAGNOSTIC AND THERAPEUTIC MANEUVERS — A variety of diagnostic and therapeutic maneuvers can be performed during colonoscopy. The most common maneuver is tissue sampling. Other interventions include:

Endoscopic hemostasis (picture 11) (see "Argon plasma coagulation in the management of gastrointestinal hemorrhage" and "Endoscopic clip therapy in the gastrointestinal tract: Bleeding lesions and beyond" and "Approach to acute lower gastrointestinal bleeding in adults", section on 'Colonoscopy')

Dilation of colonic or anastomotic strictures (see "Management of anastomotic complications of colorectal surgery", section on 'Strictures')

Stent placement for malignant disease (movie 1) (see "Enteral stents for the management of malignant colorectal obstruction")

Endoscopic mucosal resection and endoscopic submucosal dissection of gastrointestinal tumors (see "Overview of endoscopic resection of gastrointestinal tumors")

Foreign body removal (image 5 and picture 12A-B) (see "Rectal foreign bodies", section on 'Endoscopy')

Placement of a colonic decompression tube (see "Acute colonic pseudo-obstruction (Ogilvie's syndrome)", section on 'Colonoscopic decompression')

Percutaneous endoscopic cecostomy tube placement (see "Acute colonic pseudo-obstruction (Ogilvie's syndrome)", section on 'Colonoscopic decompression')

Tissue sampling — Visible lesions identified during colonoscopy should be sampled or removed for pathology. Because the colonic mucosa lacks pain receptors, patients generally do not feel pain with these maneuvers. Tissue sampling includes biopsies, brushings, and polypectomy [53]. Specimens obtained can be sent for histology, cytology, microbiology, or virology, depending upon the clinical situation. When submitting samples, the endoscopist should provide the pathologist, cytologist, or microbiologist with the patient's clinical history, endoscopic findings, and questions to be answered. Access to the endoscopy report and photographs of the sampled area may also be helpful.

Polypectomy — Most polyps less than 2 cm in size can be removed endoscopically, as well as many larger polyps, although larger polyps may require referral to an endoscopist with expertise in the removal of large polyps. Small polyps may be completely removed using biopsy forceps, while larger polyps require snare resection, with or without electrocautery. Advanced endoscopic mucosal resection and endoscopic submucosal dissection techniques are used for large polyps (typically greater than 2 cm) (picture 13). Nearly all pedunculated polyps without invasive cancer can be removed endoscopically. If polyps are too numerous for removal, representative samples should be obtained. (See "Endoscopic removal of large colon polyps" and "Clinical manifestations and diagnosis of familial adenomatous polyposis", section on 'Clinical manifestations'.)

Endoscopists should not attempt removal of polyps beyond their skill or comfort level. In such cases, the lesion may be sampled with biopsies although this may also interfere with future attempts at endoscopic resection, the area (but not the lesion) tattooed, and the patient referred to an endoscopist with expertise in the removal of large or difficult polyps. In some cases, endoscopic removal is not possible, and surgical resection is required.

PHOTODOCUMENTATION AND REPORTING — All colonoscopic procedures should include a complete report detailing the extent of the colon examined, quality of the preparation, and all normal and abnormal findings encountered. Photodocumentation greatly enhances the record and should be included when possible. The following are components of a complete report [54]:

Patient name along with the names of the personnel performing the procedure (endoscopist, nurses, assistants).

Date and time of procedure.

Patient's age and sex.

Documentation of informed consent.

Type of facility where the colonoscopy was performed.

American Society of Anesthesiologists classification (table 6).

Indication(s) for the procedure.

Sedation details, including the type, dose, level of sedation, and the provider responsible for sedation.

Extent of the examination, including reasons for an incomplete procedure, if applicable, with photodocumentation of landmarks in the cecum (appendiceal orifice, ileocecal valve, and terminal ileum, if intubated).

Bowel preparation type, dose, and quality.

Difficulty of the procedure, patient tolerance, and any special maneuvers required to complete the examination.

Type of instrument used, with model and instrument number either in the procedure or nursing report.

Colonoscopic findings with descriptions of the location, size, and morphology of lesions and whether pathology samples were obtained. For polyps, removal method, completeness of removal, whether the tissue was retrieved, and tattoo placement (if done) should be documented.

Unplanned events or complications, including any interventions performed as a result. This should include immediate events and, ideally, events occurring within 30 days following the colonoscopy.

Endoscopist's assessment based on colonoscopy findings and available clinical data.

Documentation of communication of pathology results with the patient and referring provider(s).

Recommendations including further tests, referrals, medication changes, and appointments.

COMPLICATIONS — The risk of serious complications following colonoscopy is low. In a review of 12 studies with 57,742 screening colonoscopies, serious harm occurred in 2.8 per 1000 examinations [55]. Over 85 percent of the complications occurred in the setting of polypectomy. In a second study that used a database with 2.3 million colonoscopies performed between 1997 and 2004, the overall rate of complications resulting in hospitalization was 1.98 per 1000 examinations [56]. A third study pooled data from 21 studies with nearly 2 million colonoscopies from 2001 to 2012 and reported perforation in 0.5 per 1000 colonoscopies, post-colonoscopy bleeding in 2.6 per 1000 colonoscopies and death in 2.9 per 100,000 colonoscopies [57].

The mortality rate related to colonoscopy is 0.007 percent [58].

However, the risk of colonoscopy is not constant across groups. Older adults are at increased risk for serious complications compared with younger patients. In a study of 53,220 colonoscopies, patients aged 80 to 84 years had a higher rate of serious complications compared with patients aged 66 to 69 years (8.8 per 1000 procedures versus 5.0 per 1000 procedures) [59]. The risk of serious complications was also increased among patients with comorbid conditions such as a history of stroke, chronic obstructive pulmonary disease, atrial fibrillation, and heart failure.

Complications related to sedation — Cardiopulmonary complications are the most frequent complication related to procedural sedation. Reducing the risk of sedation-associated complications requires appropriate anesthesia risk assessment of patients; management of high-risk patients by qualified medical personnel; appropriate monitoring before, during, and after the procedure; and delay of non-urgent procedures in unstable patients. Complications related to procedural sedation are discussed in detail elsewhere. (See "Adverse events related to procedural sedation for gastrointestinal endoscopy in adults".)

Complications related to preparation — All bowel preparations can cause adverse effects, which include fluid and electrolyte disturbances, nausea, vomiting, abdominal bloating, abdominal discomfort, aspiration, and esophageal tears from vomiting. Complications related to the various colonoscopy preparations are discussed in detail elsewhere. (See "Bowel preparation before colonoscopy in adults".)

Bleeding — Bleeding is usually associated with polypectomy and rarely accompanies diagnostic colonoscopy [60]. The reported rates of postpolypectomy bleeding vary (typically 1 to 2 percent), with higher rates seen with the removal of larger polyps [60-67]. The risk of postpolypectomy bleeding may be increased in patients with thrombocytopenia or coagulopathies. It has been suggested that overall, endoscopists should have postpolypectomy bleeding rates of less than one percent [37]. In addition to the increased risk seen with polypectomy, the risk of bleeding is increased with other therapeutic maneuvers such as stricture dilation and endoscopic mucosal resection. (See "Gastrointestinal endoscopy in patients with disorders of hemostasis".)

Postpolypectomy bleeding may be immediate or delayed. Immediate bleeding is associated with polypectomy techniques that do not use cautery or when blended (instead of coagulation) current is used for polypectomy. It often is recognized during the colonoscopy, in which case it typically can be treated immediately using endoscopic hemostatic methods. If not recognized at the time of colonoscopy, it can usually be managed by a repeat colonoscopy to identify and treat the bleeding site. (See "Management and prevention of bleeding after colonoscopy with polypectomy", section on 'Immediate bleeding' and "Endoscopic clip therapy in the gastrointestinal tract: Bleeding lesions and beyond", section on 'Postpolypectomy bleeding'.)

Delayed bleeding is typically seen five to seven days after the procedure, but it has been reported up to 29 days later. It is thought to occur due to sloughing of an eschar that was covering a blood vessel or due to extension of the zone of thermal necrosis to non-injured tissue, which could result in bleeding if it involves a blood vessel. Patients may present with hematochezia or with melena, depending upon the location of the bleeding (bleeding from the right colon may present as melena). As with immediate bleeding, delayed bleeding can often be managed with colonoscopy to identify and treat the bleeding site. (See "Management and prevention of bleeding after colonoscopy with polypectomy", section on 'Delayed bleeding'.)

Perforation — Perforations typically occur by one of three mechanisms: (1) mechanical trauma from pressure exerted by the colonoscope on the wall of the colon (often in the rectosigmoid region) or at the site of a stricture; (2) barotrauma, where pressure in the colon exceeds the bursting pressure of a colonic region (typically the cecum); or (3) from electrocautery injury during polypectomy. Perforation rates during colonoscopy vary with the procedure being performed [55,56,68]:

Screening colonoscopy: 0.01 to 0.1 percent

Anastomotic stricture dilation: 0 to 6 percent

Crohn disease stricture dilation: 0 to 18 percent

Stent placement: 4 percent

Colonic decompression tube placement: 2 percent

Colonic endoscopic mucosal resection 0 to 5 percent

Due to the mechanism of injury (mechanical trauma or barotrauma), perforations from a diagnostic colonoscopy are typically large. On the other hand, perforations from a therapeutic colonoscopy may be small and located at the site of the therapeutic intervention, though such patients may also suffer perforations due to mechanical trauma or barotrauma.

Mortality rates from iatrogenic colonic perforation range from 0 to 0.65 percent [69]. Risk factors for perforation include advanced age, multiple comorbidities, diverticulosis, obstruction, resection of polyps over 1 cm in size that are located in the right colon, and other therapeutic maneuvers [55,56,67,70,71]. Anesthesia for sedation may increase the risk of perforation compared with moderate procedural sedation (eg, with a narcotic and benzodiazepine) [20,72]. However, other studies have not noted this association [71,73,74]. Additional risk factors for perforation include reduced mobility of the colon, existing weakness in the colon wall, previous incomplete attempt at endoscopic removal of a colonic lesion, performance of colonoscopy by a non-gastroenterologist, and endoscopist inexperience [56,71,75-78]:

Reduced colon mobility can result from adhesions, diverticula, radiation therapy, malignancy, or infection.

Mucosal abnormalities may occur as a result of inflammatory bowel disease, malignancy, infection, radiation therapy, necrosis, or a partial tear. These abnormalities may cause weakness in the colon wall and predispose to perforation [77].

Endoscopists with low procedure volume have increased rates of perforation [75,76].

In general, perforation rates greater than 1 in 1000 screening colonoscopies or 1 in 500 for all colonoscopies should initiate evaluation of the endoscopist's technique [37]. (See 'Quality indicators' below.)

Techniques to decrease the risk of perforation include creating a fluid cushion by injection of submucosal fluid underneath large or flat polyps before resection, avoiding dilation in patients with significant inflammation in the area to be dilated, minimizing air insufflation during placement of a colonic stent, and avoiding colonic stent placement in patients who are or will be receiving bevacizumab [54,79]. (See "Enteral stents for the management of malignant colorectal obstruction", section on 'Stenting in the setting of adjunctive therapy'.)

Symptoms will vary depending upon the location and size of perforation, the degree of fecal seepage into the peritoneum, and the patient's comorbidities. Colonic perforation may be retro- or intraperitoneal. The ascending colon, hepatic and splenic flexures, and descending colon are retroperitoneal, whereas the distal rectum is below the peritoneum (figure 3). The most common symptom of a colonic perforation is abdominal pain. Other symptoms include fever, nausea, vomiting, dyspnea, chest pain, scapular pain, and neck pain. However, patients with retroperitoneal perforations may have minimal or atypical symptoms. The physical examination may be notable for diffuse or localized abdominal tenderness with peritoneal signs.

If perforation is suspected, immediate abdominal radiographs (plain and upright or lateral decubitus) and an upright chest radiograph should be obtained to look for free air under the diaphragm, retroperitoneal air, pneumomediastinum, pneumothorax, or subcutaneous emphysema. If plain films are normal but there is a high suspicion of perforation, an abdominopelvic computed tomography scan with water-soluble contrast should be obtained since it has higher sensitivity for detecting extraluminal air than plain films (particularly for retroperitoneal perforations) [80]. (See "Overview of gastrointestinal tract perforation".)

Management includes giving the patient nothing by mouth and starting intravenous fluids and intravenous broad-spectrum antibiotics. Surgical consultation should be obtained immediately. Large perforations typically require surgery. A minority of patients can be managed nonsurgically. Such patients have a clean colon with no signs of peritonitis and improve symptomatically over 24 hours. Usually these patients have a retroperitoneal perforation and/or sustained the perforation during a therapeutic colonoscopy. Reported success rates for nonsurgical management are variable (between 33 to 64 percent in some series) [81-83]. Successful endoscopic clip closure of perforations has been reported and may be attempted if the perforation is visualized at the time of the colonoscopy and is accessible [84,85]. However, colonoscopy is contraindicated in patients with a suspected perforation and is not used to treat perforations recognized after completion of the colonoscopy. (See "Endoscopic clip therapy in the gastrointestinal tract: Bleeding lesions and beyond", section on 'Perforations and fistulas' and "Endoscopic removal of large colon polyps", section on 'Complications' and "Enteral stents for the management of malignant colorectal obstruction", section on 'Stenting in the setting of adjunctive therapy'.)

Surgical treatment is indicated in patients with diffuse peritonitis, patients who deteriorate while undergoing nonsurgical treatment, and patients with a concomitant colonic lesion that requires surgery (eg, colorectal cancer) [70]. Pneumoperitoneum alone is not an indication for surgery [79].

Postpolypectomy syndrome — Postpolypectomy syndrome results from electrocoagulation injury to the bowel wall, creating a transmural burn and focal peritonitis without frank perforation. Clinical manifestations include fever, focal abdominal tenderness, and leukocytosis one to five days following polypectomy. Management includes intravenous hydration, antibiotics, and bowel rest. Outpatient management has been reported in reliable patients with mild symptoms. (See "Postpolypectomy coagulation syndrome".)

Infection — The rate of infection related to gastrointestinal endoscopy is very low. Cases of hepatitis B, hepatitis C, and bacterial transmission related to defective equipment and/or breaches in protocols for proper endoscope reprocessing have been reported. (See "Antibiotic prophylaxis for gastrointestinal endoscopic procedures" and "Preventing infection transmitted by gastrointestinal endoscopy" and "Epidemiology and transmission of hepatitis C virus infection".)

Gas explosion — Gas explosion is exceedingly rare and results from the ignition of hydrogen or methane gas in the colonic lumen from use of electrosurgical energy. The gas results from an incomplete or poor preparation or from the use of incompletely absorbable carbohydrate preparations such as lactulose, mannitol, or sorbitol. The use of argon plasma coagulation (APC) for bleeding control from radiation-induced proctitis has been associated with gas explosions when enemas were used before a sigmoidoscopy or the colonoscopy preparation was poor quality [86]. A death has been reported as a result of gas explosion during colonoscopy [87].

Gas explosion has also been reported in a patient who had previously undergone colectomy for Gardner syndrome [88]. The patient was found to have rectal polyps on proctoileoscopy. The polyps were treated with APC, resulting in the explosion, with multiple rectal and ileal perforations. The patient had not received a preparation prior to the procedure.

QUALITY INDICATORS — Multiple quality indicators have been proposed for colonoscopy including cecal intubation rates, withdrawal times, and adenoma detection rates [2]. Adenoma detection rates are calculated based upon screening colonoscopies in asymptomatic patients ≥50 years of age who are at average risk for colon polyps and colon cancer. In addition, adenoma detection rates are based only upon complete examinations with adequate preparations. The goal of applying quality indicators is to improve colonoscopy performance and decrease the number of lesions (particularly adenomas) missed during colonoscopy.

In a systematic review of six studies with 465 patients who underwent tandem colonoscopies, the overall adenoma miss rate was 22 percent, with smaller adenomas being more likely to be missed [89]:

1 to 5 mm: 26 percent miss rate

5 to 10 mm: 13 percent miss rate

≥10 mm: 2 percent miss rate

The importance of adenoma detection has been demonstrated in multiple studies [90-92]:

In a study of 45,026 patients who underwent screening colonoscopy, interval colorectal cancer (ie, cancer that developed between the time of the screening colonoscopy and the time scheduled for follow-up colonoscopy) was detected in 42 patients [90]. The endoscopists' adenoma detection rates were associated with the risk of developing an interval colorectal cancer. The rates of interval colorectal cancer were 34 per 100,000 person-years for endoscopists with an adenoma detection rate <11 percent, 22 per 100,000 person-years with an adenoma detection rate of 11 to 14.9 percent, 26 per 100,000 person-years with an adenoma detection rate of 15 to 19.9 percent, and 2 per 100,000 person-years with an adenoma detection rate ≥20 percent.

A second study looked at 314,872 colonoscopies performed for various indications in patients ≥50 years of age [91]. Adenoma detection rates were calculated based on screening examinations, but did not take into account preparation quality or whether the cecum was reached during the examination. Adenoma detection rates ranged from 7.4 to 52 percent. The rates of interval cancer declined linearly with increasing adenoma detection rate. For endoscopists with an adenoma detection rate of ≤19 percent, there were 98 interval cancers per 100,000 person-years, whereas for endoscopists with an adenoma detection rate of ≥33.5 percent, the rate was 48 per 100,000 person-years. After adjusting for confounders, the risk of interval cancer decreased 3 percent for every 1 percent increase in adenoma detection rate (hazard ratio 0.97, 95% CI 0.96-0.98).

Colorectal cancers may also be missed during colonoscopy. Studies suggest that colonoscopy will miss 2 to 6 percent of colorectal cancers. (See "Clinical presentation, diagnosis, and staging of colorectal cancer", section on 'Colonoscopy'.)

The following quality indicators were identified by a consensus panel from the American Society of Gastrointestinal Endoscopy and American College of Gastroenterology in guidelines that were updated in 2015 [2]:

There is an appropriate indication for the colonoscopy. (See 'Indications' above.)

Informed consent is obtained, including specific discussion of the risks associated with colonoscopy. (See 'Informed consent' above.)

Recommended postpolypectomy and post-cancer resection surveillance intervals are followed. (See 'Indications' above.)

Recommended ulcerative colitis/Crohn disease surveillance intervals are followed. (See 'Indications' above.)

The quality of the preparation is documented in the procedure note and adequate to allow screening and surveillance recommendations to be followed. (See 'Photodocumentation and reporting' above.)

Colonoscopists have acceptable cecal intubation rates (visualization of the cecum by notation of landmarks and photodocumentation of landmarks should be present in every procedure). Effective colonoscopists should be able to intubate the cecum in ≥90 percent of all cases and in ≥95 percent of cases when the indication is screening in a healthy adult. This does not include procedures aborted due to poor preparation or severe colitis, or those performed for the focused intent of managing strictures or large, previously diagnosed polyps.

Colonoscopists have adenoma detection rates of at least 25 percent in patients who are over the age of 50 years and are undergoing screening colonoscopy (30 percent in men and 20 percent in women).

The mean withdrawal time is ≥6 minutes in colonoscopies with normal results that are performed in patients with intact anatomy.

Biopsies specimens are obtained in patients with chronic diarrhea. (See 'Indications' above.)

An appropriate number and distribution of biopsy samples are obtained in patients undergoing ulcerative colitis and Crohn colitis surveillance. The goal is four biopsies per 10 cm section of involved colon, or approximately 32 specimens per case of pancolitis. (See "Surveillance and management of dysplasia in patients with inflammatory bowel disease", section on 'Role of random biopsies'.)

Mucosally-based pedunculated polyps and sessile polyps <2 cm in size are endoscopically resected, or documentation of unresectability is obtained. (See 'Polypectomy' above.)

Perforation rates by procedure type (all indications versus screening) are monitored. In general, the perforation rate should not exceed 1 in 500 colonoscopies overall, and 1 in 1000 screening colonoscopies. (See 'Perforation' above.)

Incidence of postpolypectomy bleeding is monitored. In general, the incidence of postpolypectomy bleeding should be less than 1 percent. (See 'Bleeding' above.)

Postpolypectomy bleeding is managed nonoperatively in ≥90 percent of cases. (See 'Bleeding' above.)

An older version of the guidelines suggested adenoma detection rates of at least 25 percent for men and 15 percent for women. However, some studies suggested that these benchmarks were too low. In a prospective series of 864 average-risk patients undergoing colonoscopy, the adenoma detection rate for men was 41 percent and for women was 25 percent (with advanced adenoma detection rates of 15 and 9 percent, respectively) [93].

One factor that has received significant attention is withdrawal time [94-97]. In a study of 2053 screening colonoscopies, endoscopists with a mean withdrawal time of ≥6 minutes had a higher neoplasia detection rate than those with a withdrawal time of less than 6 minutes (28 versus 12 percent), including advanced neoplasia (6 versus 3 percent) [94]. Similarly, in a prospective study of 315 gastroenterologists and 15,955 patients, endoscopists with a mean withdrawal time of ≥6 minutes were 1.8 times more likely to detect one or more polyps [95]. However, another prospective study that included 4429 consecutive colonoscopies performed by 67 endoscopists failed to find a statistically significant difference in polyp detection for polyps ≥5 mm for those who had median withdrawal times of ≥6 minutes compared with those with shorter withdrawal times (odds ratio 1.2; 95% CI 0.9-1.6) [96].

INFORMATION FOR PATIENTS — UpToDate offers two types of patient education materials, "The Basics" and "Beyond the Basics." The Basics patient education pieces are written in plain language, at the 5th to 6th grade reading level, and they answer the four or five key questions a patient might have about a given condition. These articles are best for patients who want a general overview and who prefer short, easy-to-read materials. Beyond the Basics patient education pieces are longer, more sophisticated, and more detailed. These articles are written at the 10th to 12th grade reading level and are best for patients who want in-depth information and are comfortable with some medical jargon.

Here are the patient education articles that are relevant to this topic. We encourage you to print or e-mail these topics to your patients. (You can also locate patient education articles on a variety of subjects by searching on "patient info" and the keyword(s) of interest.)

Basics topics (see "Patient education: Colonoscopy (The Basics)")

Beyond the Basics topics (see "Patient education: Colonoscopy (Beyond the Basics)")

SUMMARY AND RECOMMENDATIONS

Colonoscopy includes visualization of the rectum, colon, and the distal portion of terminal ileum, with real-time assessment and interpretation of the findings encountered. (See 'Introduction' above.)

Colonoscopy is indicated for the diagnostic evaluation of signs and symptoms of a wide variety of gastrointestinal disorders, for colon cancer screening, and for therapeutic interventions (table 1 and table 7 and table 8). (See 'Indications' above.)

Preparation for colonoscopy typically involves the ingestion of a low-residue diet or clear liquids for at least one day prior to the examination, combined with an oral gastrointestinal lavage. Most medications may be continued up to the time of colonoscopy, but management of antiplatelet agents and anticoagulants must take into account the procedure-related risk of bleeding and the risk of thrombosis. Antibiotic prophylaxis is not required for patients undergoing colonoscopy. (See 'Patient preparation' above and "Management of antiplatelet agents in patients undergoing endoscopic procedures" and "Management of anticoagulants in patients undergoing endoscopic procedures".)

Routine colonoscopy is performed using a high-definition white-light colonoscope. Multiple accessories are available to aid with diagnostic and therapeutic maneuvers. In addition, options are available to enhance visualization during colonoscopy (eg, chromoendoscopy), although many require specialized equipment and training. (See 'Equipment' above.)

A variety of diagnostic and therapeutic maneuvers can be performed during colonoscopy. The most common maneuver is tissue sampling, including routine polypectomy. (See 'Diagnostic and therapeutic maneuvers' above.)

Other interventions include:

Endoscopic hemostasis

Dilation of colonic strictures

Stent placement for malignant disease

Endoscopic mucosal resection and endoscopic submucosal dissection of large colonic polyps

Colonic decompression tube placement

Percutaneous endoscopic cecostomy tube placement

Foreign body removal

Serious complications of colonoscopy are rare (approximately 3 per 1000 screening colonoscopies) and include complications of sedation, complications related to the preparation, bleeding, and perforation. (See 'Complications' above and "Adverse events related to procedural sedation for gastrointestinal endoscopy in adults" and "Bowel preparation before colonoscopy in adults".)

Bleeding is usually associated with polypectomy and rarely accompanies diagnostic colonoscopy. Postpolypectomy bleeding occurs in approximately 1 to 2 percent of polypectomies, with higher rates seen with the removal of larger polyps. Patients may present with hematochezia or melena days to weeks after the colonoscopy. The majority of patients can be managed with a repeat colonoscopy to both identify and treat the source of bleeding. (See 'Bleeding' above and "Management and prevention of bleeding after colonoscopy with polypectomy".)

Perforation rates vary with the procedure being performed, with rates of 0.01 to 0.1 percent for screening colonoscopy. The most common symptom of a colonic perforation is abdominal pain. Other symptoms include fever, nausea, vomiting, dyspnea, chest pain, scapular pain, and neck pain. However, patients with retroperitoneal perforations may have minimal or atypical symptoms. The physical examination may be notable for diffuse or localized abdominal tenderness with peritoneal signs. (See 'Perforation' above.)

If perforation is suspected, immediate abdominal radiographs (plain and upright or lateral decubitus) and an upright chest radiograph should be obtained. If plain films are normal but there is a high suspicion of perforation, an abdominopelvic computed tomography scan with water-soluble contrast should be obtained. All patients with perforations should receive intravenous fluids and broad spectrum antibiotics. Many patients with perforations will require surgery, though nonsurgical management may be possible in those with small perforations without evidence of peritonitis.

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