ABSTRACT
Background
Endoscopic mucosal resection (EMR) is an easy-to-use treatment option for superficial colorectal lesions, including lesions ≥20 mm.
Objective
To evaluate the effectiveness of EMR.
Methods
We evaluated 430 lesions removed by EMR in 404 patients. The lesions were analyzed according to their morphology, size, location, and histology. Lesions <20 mm were resected en bloc, whereas lesions ≥20 mm were removed by piecemeal EMR (p-EMR). Adverse events and recurrence were assessed.
Results
Regarding morphology, 145 (33.7%) were depressed lesions, 157 (36.5%) were polypoid lesions and 128 (29.8%) were laterally spreading lesions, with 361 (84%) lesions <20 mm and 69 (16%) ≥20 mm. Regarding histology, 413 (96%) lesions were classified as neoplastic lesions. Overall, 14 (3.3%) adverse reactions occurred, most commonly in lesions removed by p-EMR (P<0.001) and associated with advanced histology (P=0.008). Recurrence occurred in 14 (5.2%) cases, more commonly in lesions removed by p-EMR (P<0.001).
Conclusion
EMR is an effective technique for the treatment of superficial colorectal lesions, even of large lesions.
Keywords:
Colonic polyps; adenoma; colonoscopy; endoscopic mucosal resection; large lesions; colorectal neoplasm
RESUMO
Contexto
Ressecção endoscópica da mucosa (REM) é uma opção fácil para o tratamento das lesões superficiais do cólon e reto, inclusive para as lesões ≥20 mm de diâmetro.
Objetivo
Avaliar a efetividade da REM.
Métodos
Este estudo prospectivo observacional avaliou 430 lesões ressecadas por REM em 404 pacientes. As lesões foram analisadas de acordo com a morfologia, tamanho, localização e histologia. Lesões <20 mm foram removidas em bloco, enquanto lesões ≥20 mm foram ressecadas em piecemeal REM (p-REM). Eventos adversos e recorrência foram avaliados.
Resultados
Quanto à morfologia, 145 (33,7%) eram lesões deprimidas, 157 (36,5%) eram lesões polipoides e 128 (29,8%) eram lesões que se espalham lateralmente, com 361 (84%) lesões <20 mm e 69 (16%) ≥20 mm. Em relação à histologia, 413 (96%) foram classificadas como lesões neoplásicas. Globalmente tivemos 14 (3,3%) de reações adversas, mais presente nas lesões ≥20 mm removidas por p-REM (P<0,001) e associadas com histologia avançada (P=0,008). A recorrência ocorreu em 14 (5,2%) casos, sendo mais observada em lesões removidas por p-REM (P<0,001).
Conclusão
REM é uma técnica efetiva para o tratamento das lesões colorretais superficiais, até mesmo para as grandes lesões.
Palavras-chave:
Pólipos colônicos; adenoma; colonoscopia; ressecção endoscópica; grandes lesões; neoplasia colorretal
INTRODUCTION
Endoscopic removal of colorectal lesions reduces the incidence and mortality of colorectal cancer (CRC), proving to be a decisive tool in its prevention11. Zauber AG, WinawerSJ, O’Brien MJ, Lansdorp-Vogelaar I, van Ballegooijen M, Hankey BF, et al. Colonoscopic polypectomy and long-term prevention of colorectal-cancer deaths. N Engl J Med. 2012;366:687-96.. A number of techniques have been proposed, ranging from a simple polypectomy to endoscopic submucosal dissection (ESD). Endoscopic mucosal resection (EMR) is considered the first-line treatment for most superficial lesions22. Santos CE, Malaman D, Pereira-Lima JC. Endoscopic mucosal resection in colorectal lesion: a safe and effective procedure even in lesions larger than 2 cm and in carcinomas. Arq Gastroenterol. 2011;48:242-7.,33. Lee EY, Bourke MJ. EMR should be the first-line treatment for large laterally spreading colorectal lesions. Gastrointest Endosc. 2016;84:326-8..
Inject-and-cut EMR is the most commonly used EMR technique. Currently, in addition to saline solution, colloid solutions are most commonly used.
It is important to recognize the individual characteristics of the lesions to be resected, as well as the predictive histological diagnosis in order to select the most appropriate approach. EMR represents a major advance in endoscopic treatment by allowing en bloc resection of superficial lesions <20 mm. Lesions ≥20 mm pose a greater challenge as they require a resection piece by piece, called piecemeal EMR (p-EMR). The main criticisms of p-EMR are higher recurrence or residual lesion rates. ESD is also an option for these lesions, allowing en bloc resection with lower recurrence; however, it is associated with a higher risk of perforation and requires a long learning curve44. Kaltenbach T, Anderson JC, Burke CA, Dominitz JA, Gupta S, Lieberman D, et al. Endoscopic Removal of Colorectal Lesions - Recommendations by the US Multi-SocietyTask Force on Colorectal Cancer. Gastroenterology. 2020;158:1095-1129..
For the management of large non-pedunculated colorectal neoplasms, the European Society of Gastrointestinal Endoscopy (ESGE) Clinical Guideline suggests that most of these lesions can be treated with p-EMR55. Ferlitsch M, Moss A, Hassan C, Bhandari P, Dumonceau JM, Paspatis G, et al. Colorectal polypectomy and endoscopic mucosal resection (EMR): European Society of Gastrointestinal Endoscopy (ESGE) ClinicalGuideline. Endoscopy. 2017;49:270-97.. To reduce this risk caused by local recurrence after EMR, it is recommended that the first follow-up be performed between two and six months after endoscopic resection66. Tanaka S, Kashida H, Saito Y, Yahagi N, Yamano H, Saito S, et al. Japan Gastroenterological Endoscopy Society guidelines for colorectal endoscopic submucosal dissection/endoscopic mucosal resection. Dig Endosc. 2020;32:219-39.,77. Rutter MD, Chattree A, Barbour JA, Thomas-Gibson S, Bhandari P, Saunders BP, et al. British Society of Gastroenterology/Association of Coloproctologists of Great Britain and Ireland guidelines for the management oflarge non-pedunculated colorectalpolyps. Gut. 2015;64:1847-73..
The objective of the present study was to evaluate the effectiveness of EMR.
METHODS
Study design
This prospective cross-sectional study was conducted in the Department of Endoscopy at Hospital Santa Casa de Caridade de Bagé, Brazil. It was approved by the Research Ethics Committee of the institution and conducted in accordance with the Declaration of Helsinki. Written informed consent was obtained from all individual participants.
Patients
From January 2008 to December 2019, 430 EMRs of the colon and rectum were performed in 404 patients. Mean patient age was 62.4±10.4 years (range, 34-94 years), and 206 (51%) were men.
Equipment
After detection with white-light imaging, magnification chromoendoscopy with 0.4% indigo-carmine or image-enhancement endoscopy (IEE) were used for pit and capillary pattern analysis. High-definition colonoscopes were used, including LASEREO system since 2015.
Lesions’ characteristics
All lesions showed an endoscopic appearance that suggested the depth was limited to the mucosa or submucosa. The Paris classification was used to describe the morphology of the lesions88. No authors listed. The Paris endoscopic classification of superficial neoplastic lesions: Gastrointest Endosc. 2003;58 (Suppl 6):S3-43. doi: 10.1016/s0016-5107(03)02159-x.
https://doi.org/10.1016/s0016-5107(03)02...
. According to Kudo et al.99. Kudo S, Lambert R, Allen JI, Fujii H, Fujii T, Kashida H, et al. Nonpolypoid neoplastic lesions of the colorectal mucosa. Gastrointest Endosc. 2008;68 (Suppl 4):S3-47., LSLs were classified as granular (LSL-G), divided into homogeneous (LSL-G-H) and nodular mixed (LSL-G-N) subtypes and non-granular (LSL-NG), subclassified into flat elevated (LSL-NG-FE) and pseudo-depressed (LSL-NG-PD) subtypes.
Lesions subjected to EMR had pit and capillary patterns, according to the Kudo-Kimura and Teixeira classifications, respectively, suggestive of neoplastic lesion without massive submucosal invasion and were, therefore, amenable to endoscopic treatment1010. Kudo S, Tamura S, Nakajima T, Yamano H, Kusaka H, Watanabe H. Diagnosis of colorectal tumours lesions by magnifying endoscopy. Gastrointest Endosc . 1996;44:8-14.
11. Kimura T, Yamamoto E, Yamano HO, Suzuki H, Kamimae S, Nojima M, et al. A Novel Pit Pattern Identifies the Precursor of Colorectal Cancer Derived From Sessile Serrated Adenoma. Am J Gastroenterol. 2012;107:460-9.-1212. Teixeira CR, Torresini RS, Canali C, Figueiredo LF, Mucenic M, Lima JCP, et al. Endoscopic classification of the capillary-vessel pattern of colorectal lesions by spectral estimation technology and magnifying imaging. Gastrointest Endosc . 2009;69:750-6.. All lesions were analyzed by an endoscopist with experience in IEE.
Advanced histology was defined as high-grade dysplasia or early carcinoma.
Endoscopic procedures
EMR was indicated in cases of superficial depressed lesions, sessile lesions ≥10 mm in diameter and LSLs. The inject-and-cut technique used a hypertonic saline solution - 4% sodium chloride. Lesion characteristics such as size, morphology, location, and histology were evaluated, as well as adverse events and recurrence of the endoscopic procedure. Lesion size was measured with open biopsy forceps. Location was divided into the right colon segment (from the transverse colon to the cecum) and the left colon segment (from the rectum to the descending colon).
For histological analysis, specimens were mounted on Styrofoam plates, fixed in 10% formalin, and then evaluated according to the World Health Organization classification for histopathology1313. Hamilton SR, Aaltonen LA, editors: World Health Organization classification of tumours. Pathology and genetics of tumours of the digestive system. Lyon: IARC Press: 2000;104-119..
Lesions <20 mm were resected en bloc, whereas lesions ≥20 mm were removed by p-EMR (Figure 1) in a single session. Bleeding was divided into intraprocedural and delayed (after discharge from the endoscopy department). Prophylactic clipping was not performed to close the post-EMR defect.
A) LSL-G-N subtype; B) Fibrosis area; C) Injection of 4% NaCl under the lesion; D-E) Piecemeal EMR; F) Post-resection; G) Post-resection and APC; H) Scar.
Recurrence (or residual neoplasm) was defined as the presence of neoplastic tissue in the area of previous resection, as diagnosed by follow-up colonoscopy. Patients underwent follow-up at 3-6 and 12 months. Recurrent/residual mucosal lesions were treated with a second EMR and identified by the scar.
Argon plasma coagulation (APC) was used in the resection margin in 46 lesions ≥20 mm in a sequential, non-randomized manner. APC was not used in the first 23 lesions ≥20 mm.
Statistical analysis
Statistical analysis was performed using Stata, version 15.1. Categorical variables were expressed as absolute and relative frequencies and analyzed by Fisher’s exact test. Numerical variables were expressed as mean and standard deviation and analyzed by analysis of variance (ANOVA). The significance level was set at 5% for two-tailed tests.
RESULTS
EMR was performed in 430 lesions, of which 145 (33.7%) were depressed lesions, 157 (36.5%) were polypoid lesions and 128 (29.8%) were LSLs. The mean lesion size was 12.2±9.8 mm; 361 (84%) lesions were < 20 mm and 69 (16%) were ≥20 mm, removed en bloc and by p-EMR, respectively. Distribution of lesions’ size is shown in Table 1. Regarding histology, 413 (96%) as neoplastic lesions (adenomas and early carcinomas) (Table 2). Advanced histology was more frequently observed in lesions removed by p-EMR than in lesions resected en bloc (50.7% vs 19.5%, P<0.001). Descriptive analysis of lesions with advanced histology is shown in Table 3.
A total of 128 LSLs were removed endoscopically. Granular LSL-G-N subtype were significantly larger (P<0.001) and were more commonly subjected to p-EMR (P=0.003), with higher recurrence (P=0.02) and more adverse events (P=0.03). Advanced histology was more frequently observed in the pseudo-depressed (62.5%) and nodular mixed (53.9%) subtypes, with statistical significance in relation to the other subtypes (P<0.001) (Table 4).
Overall, 14 (3.3%) adverse reactions occurred, most commonly in lesions removed by p-EMR (17.4% vs 0.6%, P<0.001) and associated with advanced histology (P=0.008). Intraprocedural bleeding occurred in 13 (3%) of all EMRs, with 11 cases of minor bleeding, controlled with injection therapy or APC. There were two cases of major bleeding. One occurred after p-EMR of a LSL-G-H subtype, measuring about 40 mm and located in the cecum, which was controlled with APC. After 36 hours, the patient developed pneumoperitoneum and was referred for surgery. The other case of major bleeding occurred after en bloc EMR of a polypoid intramucosal adenocarcinoma with superficial submucosal invasion, located in the rectum, and was controlled with the application of endoclips. There were no cases of delayed bleeding.
Post-EMR micro-perforation occurred in one case of a LSL-G-N subtype, measuring about 50 mm and located in the rectum. The case was managed conservatively with hospitalization, hydration, and antibiotics. There were no deaths.
A total of 272 (63.3%) lesions were followed up, with the first follow-up at 3-6 months, and then at 12 months after the index EMR, being 210 lesions (58.2% of lesions <20 mm) that were resected en bloc and 62 lesions (89.9% of lesions ≥20 mm) that were removed by p-EMR. Recurrence occurred in 14 (5.2%) cases, all detected at first follow-up, and was more common in lesions removed by p-EMR (17.4% vs 0.6%, P<0.001). Thirteen (92.9%) of the residual/recurrent lesions were successfully treated with a second EMR.
Of 69 lesions ≥20 mm, 46 received complementary APC in the resection margin. This group had a 15.2% recurrence rate, whereas the group that did not receive APC had a 21.7% recurrence rate (P=0.5).
DISCUSSION
EMR is a safe and effective tumor resection technique, even for large lesions. This approach offers an interesting alternative to surgery, including treatment of early carcinomas with superficial submucosal invasion. Chromoendoscopy and IEE are considered effectives resources in the characterization of colorectal lesions and in the risk stratification of submucosal invasion through pit and capillary pattern analysis1414. Kanao H, Tanaka S, Oka S, Kaneko I, Yoshida S, Arihiro K, et al. Clinical significance of type VI pit pattern subclassification in determining the depth of invasion of colorectal neoplasms. World J Gastroenterol 2008;14:211-7.
15. Dos Santos CE, Perez HJ, Mönkemüller K, Malaman D, Lopes CV, Pereira-Lima JC. Observer agreement for diagnosis of colorectal lesions with analysis of the vascular pattern by image-enhanced endoscopy. EndoscInt Open. 2015;3:E240-5.-1616. Dos Santos CEO, Malaman D, Yoshida N, Pereira-Lima JC, Onófrio FQ, Furlan RG, et al. Blue laser imaging: a new image-enhanced endoscopy for the diagnosis of colorectal lesions. Eur J Gastroenterol Hepatol. 2018;30:1514-20.. Proficiency in the use of IEE techniques has been suggested and recommended for endoscopic recognition of submucosal invasion55. Ferlitsch M, Moss A, Hassan C, Bhandari P, Dumonceau JM, Paspatis G, et al. Colorectal polypectomy and endoscopic mucosal resection (EMR): European Society of Gastrointestinal Endoscopy (ESGE) ClinicalGuideline. Endoscopy. 2017;49:270-97.. Kawaguti et al.1717. Kawaguti FS, Franco MC, Martins BC, Segateli V, Marques CFS, Nahas CSR, et al. Role of Magnification Chromoendoscopy in the Management of Colorectal Neoplastic Lesions Suspicious for Submucosal Invasion. Dis Colon Rectum. 2019;62:422-8. demonstrated 96.7% accuracy in the assessment of large lesions suspicious for submucosal invasion using pit pattern analysis for the predictive endoscopic diagnosis. In the present study, the endoscopist had expertise in IEE. Seventeen (4%) hyperplastic lesions with a type II-O pit pattern were resected, i.e., with high specificity for sessile serrated adenoma/polyp (SSA/P). The high variability that still exists among pathologists in the differential diagnosis of hyperplastic polyps and SSA/Ps may explain this difference in diagnosis.
Yandrapu et al.1818. Yandrapu H, Desai M, Siddique S, Vennalganti P, Vennalaganti S, Parasa S, et al. Normal saline solution versus other viscous solutions for submucosal injection during endoscopic mucosal resection: a systematic review and meta-analysis. Gastrointes Endosc. 2017;85:693-9. demonstrated higher rates of en bloc resection (P=0.02) and lower rates of residual lesions (P=0.02) with the use of colloid solution compared with normal saline solution for lesions >20 mm. In the present study, hypertonic saline solution was used in all cases.
Advances in endoscopic resection techniques should reduce the rate of surgical indication in lesions amenable to endoscopic treatment, decreasing the rate of adverse events, and costs. Peery et al.1919. Peery AF, Cools KS, Strassle PD, McGill SK, Crockett SD, Barker A, et al. Increasing Rates of Surgery for Patients With Nonmalignant Colorectal Polyps in the United States. Gastroenterology. 2018;154:1352-60.e3. reported an increase in the incidence of surgery for non-malignant polyps from 5.9 to 9.4 per 100.000 adults. In a series of 262.843 surgical procedures for non-malignant colorectal polyps, the morbidity was 25.3%, and patients developing a postoperative adverse event had increase in mean hospital length of stay (P<0.0001) and in mean hospitalization costs (P<0.0001)2020. Ma C, Teriaky A, Sheh S, Forbes N, Heitman SJ, Jue TL, et al. Morbidity and Mortality After Surgery for Nonmalignant Colorectal Polyps: A 10-Year Nationwide Analysis. Am J Gastroenterol . 2019;114:1802-10.. Hassan et al.2121. Hassan C, Repici A, Sharma P, Correale L, Zullo A, Bretthauer M, et al. Efficacy and safety of endoscopicresection of large colorectal polyps: a systematic review and meta-analysis. Gut 2016;65:806-20. showed that 14% of the patients were immediately referred for surgery before any attempt at endoscopic resection, mainly because of the endoscopic appearance suggestive of submucosal invasion. In the present study, one patient was referred for surgery, in whom bowel perforation was detected 36 hours after the use of APC to control post-EMR massive bleeding.
A meta-analysis showed that most large LSLs are non-invasive (91.5%) and, therefore, can be treated with p-EMR. LSLs measuring 20-29 mm and ≥30 mm have a 9.2% and 16.5% risk of submucosal invasion, respectively, and that invasive lesions are more common in the pseudo-depressed (31.6%) and nodular mixed (10.5%) subtypes2222. Bogie RMM, Veldman MHJ, Snijders LARS, Winkens B, Kaltenbach T, Masclee AAM, et al. Endoscopic subtypes of colorectal laterally spreading tumors (LSTs) and the risk of submucosal invasion: a meta-analysis. Endoscopy 2018;50:263-82.. In the present study, advanced histology was more frequently observed in the pseudo-depressed (62.5%) and nodular mixed (53.9%) subtypes, with statistical significance (P<0.001). Overall, advanced histology was more noticeable in lesions that were resected by the piecemeal technique (P<0.001).
ESD presents significant adverse events in the initial training phase, and its use is limited to centers of excellence in Western countries. Russo et al.2323. Russo P, Barbeiro S, Awadie H, Libânio D, Dinis-Ribeiro M, Bourke M. Management of colorectal laterally spreading tumors: a systematic review and meta-analysis. Endosc Int Open. 2019;7:E239-59. showed similar results for EMR and ESD of LSLs in terms of complete resection and curative resection. Bleeding occurred in 9.6% of EMRs and 2.8% of ESDs, especially immediate minor bleeding. Bleeding was more frequent in the removal of LSL-G than LSL-NG (OR 2.46). The present study found a rate of 3.3% of adverse reactions, which were more frequent in lesions removed by p-EMR (P<0.001) and associated with advanced histology (P=0.008). EMR of LSL-G-N subtype resulted in more complications (P=0.03). Intraprocedural bleeding occurred in 3% of all EMRs, with minor bleeding in 11 of the 13 cases, controlled with endoscopic therapy. There were two cases of major bleeding, progressing to perforation after APC, and the other occurred after en bloc EMR of an invasive carcinoma and was controlled with the application of endoclips.
A recent meta-analysis concluded that routine use of prophylactic clipping does not reduce the overall risk of bleeding after polypectomy, but it showed a reduced risk of bleeding after resection of lesions ≥20 mm (P=0.02) or located in the proximal colon (P<0.001)2424. Spadaccini M, Albéniz E, Pohl H, Maselli R, Thoguluva Chandrasekar V, et al. Prophylatic clipping after colorectal endoscopic resection prevents bleeding of large, proximal polyps: meta-analysis of randomized trials. Gastroenterology 2020;159:148-158.e11.. Prophylactic clipping was not used in any of our patients.
Perforation is one of the most feared adverse events of endoscopic resection. In a recent meta-analysis, the risk of perforation was higher in ESD than in EMR (5.9% vs 1.2%)2323. Russo P, Barbeiro S, Awadie H, Libânio D, Dinis-Ribeiro M, Bourke M. Management of colorectal laterally spreading tumors: a systematic review and meta-analysis. Endosc Int Open. 2019;7:E239-59.. We had one case of micro-perforation in a giant LSL-G-N subtype, which was successfully treated conservatively.
The main criticism of EMR is the relatively high recurrence rate. In a meta-analysis, Belderbos et al.2525. Belderbos TD, Leenders M, Moons LM, Siersema PD. Local recurrence after endoscopic mucosal resection of nonpedunculated colorectal lesions: systematic review and meta-analysis. Endoscopy 2014;46:388-402. identified a significantly higher risk of recurrence after p-EMR than after en bloc resection (P<0.0001). Most recurrences (88%) were found during the first follow-up colonoscopy, with a higher prevalence among carcinomas (P<0.001), and p-EMR was recognized as the only risk factor associated with recurrence. In previous studies by our group, we showed a significant association of the recurrence of lesions removed by p-EMR and with advanced histology22. Santos CE, Malaman D, Pereira-Lima JC. Endoscopic mucosal resection in colorectal lesion: a safe and effective procedure even in lesions larger than 2 cm and in carcinomas. Arq Gastroenterol. 2011;48:242-7.,2626. Dos Santos CEO, Pereira-Lima JC, Malaman D, Carvalho TS, Bonotto ML. Prevalence and clinicopathologic features of colorectal laterally spreading tumors in Brazil. Acta Gastroenterol Latinoam 2016;46:184-91.. In the present study, recurrence was 5.2% and associated with p-EMR (P<0.001). Although recurrence occurred often (almost a fifth of the cases) after p-EMR in larger lesions, they could be successfully managed by a new EMR during follow-up. When only LSLs were analyzed, recurrence was associated with the nodular mixed subtype (P=0.02), and in all cases the residual lesion was relatively small and amenable to successful endoscopic retreatment. There were no cases of late recurrence in the present study.
The use of APC remains controversial. A multi-center study showed lower recurrence at first follow-up in patients undergoing thermal ablation of the post-EMR mucosal defect than in controls receiving no additional treatment (P<0.001), which was directly related to the p-EMR (P<0.001) and lesion size ≥40 mm (P=0.001)2727. Klein A, Tate DJ, Jayasekeran V, Hourigan L, Singh R, Brown G, et al. Thermal Ablation of Mucosal Defect Margins Reduces Adenoma Recurrence After Colonic Endoscopic Mucosal Resection. Gastroenterology 2019;156:604-613.e3.. In the present study, 69 lesions ≥20 mm were removed by p-EMR; of these, 46 received complementary APC of the post-EMR mucosal defect margin. Lower recurrence was observed in this group, but without significance (P=0.5).
The present study has some limitations. First, the study was conducted in a single endoscopy unit. Second, all procedures were performed by the same endoscopist. Third, the endoscopist had experience in EMR, which may have contributed to the low rate of serious complications. Fourth, the endoscopist had expertise in chromoendoscopy and IEE, correctly recognizing the lesions that had an indication for endoscopic resection.
In conclusion, this study showed that EMR is a safe and effective procedure for removing superficial neoplasms of the colon and rectum, remaining a viable option in the 21st century, and even allowing the curative resection of large lesions and early carcinomas with a low rate of serious adverse events.
REFERENCES
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1Zauber AG, WinawerSJ, O’Brien MJ, Lansdorp-Vogelaar I, van Ballegooijen M, Hankey BF, et al. Colonoscopic polypectomy and long-term prevention of colorectal-cancer deaths. N Engl J Med. 2012;366:687-96.
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2Santos CE, Malaman D, Pereira-Lima JC. Endoscopic mucosal resection in colorectal lesion: a safe and effective procedure even in lesions larger than 2 cm and in carcinomas. Arq Gastroenterol. 2011;48:242-7.
-
3Lee EY, Bourke MJ. EMR should be the first-line treatment for large laterally spreading colorectal lesions. Gastrointest Endosc. 2016;84:326-8.
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4Kaltenbach T, Anderson JC, Burke CA, Dominitz JA, Gupta S, Lieberman D, et al. Endoscopic Removal of Colorectal Lesions - Recommendations by the US Multi-SocietyTask Force on Colorectal Cancer. Gastroenterology. 2020;158:1095-1129.
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5Ferlitsch M, Moss A, Hassan C, Bhandari P, Dumonceau JM, Paspatis G, et al. Colorectal polypectomy and endoscopic mucosal resection (EMR): European Society of Gastrointestinal Endoscopy (ESGE) ClinicalGuideline. Endoscopy. 2017;49:270-97.
-
6Tanaka S, Kashida H, Saito Y, Yahagi N, Yamano H, Saito S, et al. Japan Gastroenterological Endoscopy Society guidelines for colorectal endoscopic submucosal dissection/endoscopic mucosal resection. Dig Endosc. 2020;32:219-39.
-
7Rutter MD, Chattree A, Barbour JA, Thomas-Gibson S, Bhandari P, Saunders BP, et al. British Society of Gastroenterology/Association of Coloproctologists of Great Britain and Ireland guidelines for the management oflarge non-pedunculated colorectalpolyps. Gut. 2015;64:1847-73.
-
8No authors listed The Paris endoscopic classification of superficial neoplastic lesions: Gastrointest Endosc. 2003;58 (Suppl 6):S3-43. doi: 10.1016/s0016-5107(03)02159-x.
» https://doi.org/10.1016/s0016-5107(03)02159-x -
9Kudo S, Lambert R, Allen JI, Fujii H, Fujii T, Kashida H, et al. Nonpolypoid neoplastic lesions of the colorectal mucosa. Gastrointest Endosc. 2008;68 (Suppl 4):S3-47.
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10Kudo S, Tamura S, Nakajima T, Yamano H, Kusaka H, Watanabe H. Diagnosis of colorectal tumours lesions by magnifying endoscopy. Gastrointest Endosc . 1996;44:8-14.
-
11Kimura T, Yamamoto E, Yamano HO, Suzuki H, Kamimae S, Nojima M, et al. A Novel Pit Pattern Identifies the Precursor of Colorectal Cancer Derived From Sessile Serrated Adenoma. Am J Gastroenterol. 2012;107:460-9.
-
12Teixeira CR, Torresini RS, Canali C, Figueiredo LF, Mucenic M, Lima JCP, et al. Endoscopic classification of the capillary-vessel pattern of colorectal lesions by spectral estimation technology and magnifying imaging. Gastrointest Endosc . 2009;69:750-6.
-
13Hamilton SR, Aaltonen LA, editors: World Health Organization classification of tumours. Pathology and genetics of tumours of the digestive system. Lyon: IARC Press: 2000;104-119.
-
14Kanao H, Tanaka S, Oka S, Kaneko I, Yoshida S, Arihiro K, et al. Clinical significance of type VI pit pattern subclassification in determining the depth of invasion of colorectal neoplasms. World J Gastroenterol 2008;14:211-7.
-
15Dos Santos CE, Perez HJ, Mönkemüller K, Malaman D, Lopes CV, Pereira-Lima JC. Observer agreement for diagnosis of colorectal lesions with analysis of the vascular pattern by image-enhanced endoscopy. EndoscInt Open. 2015;3:E240-5.
-
16Dos Santos CEO, Malaman D, Yoshida N, Pereira-Lima JC, Onófrio FQ, Furlan RG, et al. Blue laser imaging: a new image-enhanced endoscopy for the diagnosis of colorectal lesions. Eur J Gastroenterol Hepatol. 2018;30:1514-20.
-
17Kawaguti FS, Franco MC, Martins BC, Segateli V, Marques CFS, Nahas CSR, et al. Role of Magnification Chromoendoscopy in the Management of Colorectal Neoplastic Lesions Suspicious for Submucosal Invasion. Dis Colon Rectum. 2019;62:422-8.
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18Yandrapu H, Desai M, Siddique S, Vennalganti P, Vennalaganti S, Parasa S, et al. Normal saline solution versus other viscous solutions for submucosal injection during endoscopic mucosal resection: a systematic review and meta-analysis. Gastrointes Endosc. 2017;85:693-9.
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19Peery AF, Cools KS, Strassle PD, McGill SK, Crockett SD, Barker A, et al. Increasing Rates of Surgery for Patients With Nonmalignant Colorectal Polyps in the United States. Gastroenterology. 2018;154:1352-60.e3.
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20Ma C, Teriaky A, Sheh S, Forbes N, Heitman SJ, Jue TL, et al. Morbidity and Mortality After Surgery for Nonmalignant Colorectal Polyps: A 10-Year Nationwide Analysis. Am J Gastroenterol . 2019;114:1802-10.
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21Hassan C, Repici A, Sharma P, Correale L, Zullo A, Bretthauer M, et al. Efficacy and safety of endoscopicresection of large colorectal polyps: a systematic review and meta-analysis. Gut 2016;65:806-20.
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22Bogie RMM, Veldman MHJ, Snijders LARS, Winkens B, Kaltenbach T, Masclee AAM, et al. Endoscopic subtypes of colorectal laterally spreading tumors (LSTs) and the risk of submucosal invasion: a meta-analysis. Endoscopy 2018;50:263-82.
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23Russo P, Barbeiro S, Awadie H, Libânio D, Dinis-Ribeiro M, Bourke M. Management of colorectal laterally spreading tumors: a systematic review and meta-analysis. Endosc Int Open. 2019;7:E239-59.
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24Spadaccini M, Albéniz E, Pohl H, Maselli R, Thoguluva Chandrasekar V, et al. Prophylatic clipping after colorectal endoscopic resection prevents bleeding of large, proximal polyps: meta-analysis of randomized trials. Gastroenterology 2020;159:148-158.e11.
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25Belderbos TD, Leenders M, Moons LM, Siersema PD. Local recurrence after endoscopic mucosal resection of nonpedunculated colorectal lesions: systematic review and meta-analysis. Endoscopy 2014;46:388-402.
-
26Dos Santos CEO, Pereira-Lima JC, Malaman D, Carvalho TS, Bonotto ML. Prevalence and clinicopathologic features of colorectal laterally spreading tumors in Brazil. Acta Gastroenterol Latinoam 2016;46:184-91.
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Disclosure of funding: no funding received
Publication Dates
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Publication in this collection
15 Apr 2022 -
Date of issue
Jan-Mar 2022
History
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Received
06 Apr 2021 -
Accepted
06 Aug 2021