Affiliations of authors: N. Segnan, C. Senore (Unit of Epidemiology), Centro per la Prevenzione Oncologica (CPO), Piemonte, Torino, Italy; B. Andreoni (Unit of Surgery II), C. Crosta (Unit of Gastroenterology), European Institute of Oncology, Milano, Italy; H. Aste, Department of Oncology, Biology, and Genetics, University of Genova, Italy, and Unit of Gastroenterology and Nutrition, National Institute for Cancer Research, Genova; L. Bonelli (Unit of Clinical Epidemology and Trials), S. Sciallero (Unit of Gastroenterology and Nutrition), National Institute for Cancer Research, Genova; R. Ferraris, Unit of Gastroenterology, Mauriziano "Umberto I" Hospital, Torino, Italy; S. Gasperoni, Unit of Gastroenterology, Infermi Hospital, Rimini, Italy; A. Penna, Fondo "E Tempia," Azienda Sanitaria Locale (ASL), 12, Biella, Italy; M. Risio, Unit of Pathology (IRCC), Candiolo, Torino; F. P. Rossini Unit of Gastroenterology, San Giovanni AS Hospital, Torino; M. Zappa, Unit of Clinical Epidemology, Centro per lo Studio e la Prevenzione Oncologia (CSPO), Firenze, Italy; W. S. Atkin, Imperial Cancer Research Fund, Colorectal Cancer Unit, Harrow, Middlesex, U.K.
Correspondence to: Nereo Segnan, M.D., M.S. Epi, Unita di Epidemiologia, CPO - Piemonte, Azienda Sanitaria Ospedaliero (ASO), "S Giovanni Battista," Via S Francesco da Paola 31, 10123 Torino, Italy (e-mail: nereo.segnan{at}cpo.it).
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ABSTRACT |
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INTRODUCTION |
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The protective effect of endoscopic polipectomy supports the hypothesis that colorectal carcinomas arise from adenomas, with an estimated average transition time to malignancy of approximately 1015 years (1214). Based on these findings, it was estimated that a single sigmoidoscopy screen might be a cost-effective and feasible strategy for colorectal cancer screening among individuals at average risk for the disease (15). Two further observations provide support for the idea that a single sigmoidoscopy screen may be effective in preventing a considerable proportion of colorectal cancer: the prevalence of distal adenomas in asymptomatic individuals appears to reach a plateau at around the age of 60 years (15), and data from European Cancer Registries show that among patients aged 5574 years about two thirds of colorectal carcinomas are located in the rectum or sigmoid colon (16).
A controlled trial of "once-only" sigmoidoscopy screening for colorectal cancer (the SCORE trial) was undertaken in Italy as a parallel study to a multicenter trial in the United Kingdom (17,18). The goal of these trials was to measure the extent of reduction in colorectal cancer incidence and mortality achieved by a single screening sigmoidoscopy examination and to determine both the optimum age interval (i.e., 5559 or 6064 years of age) for screening and the duration of the protective effect of a single test. The recruitment and screening phases of the SCORE trial have now been completed. Here we report on results concerning the neoplasia detection rate and safety and acceptability of this method of screening.
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SUBJECTS AND METHODS |
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Approval for the study was granted by the local ethics review committees in each center. Subjects were identified either through physicians or directly. In Arezzo, Rimini, and Torino, the target population was selected from the patients of a random sample of general practitioners drawn from the National Health Service (NHS) list of those working in the study areas. In Milano, the patients were selected from the list of all general practitioners who were invited and volunteered to cooperate. In Genova and Biella, a random sample of individuals in the target age range was drawn directly from the NHS register. All individuals aged 5564 years included in these samples (that is, resident in the study areas and listed in the NHS lists that provided their names) were mailed a questionnaire designed to assess their eligibility for and interest in screening, with an accompanying letter giving brief information about the sigmoidoscopy and explaining the rationale for the study. A prepaid envelope for returning the questionnaire was also provided. No reminder was sent to nonresponders. Responders were excluded if they reported a history of colorectal cancer, colorectal polyps, or inflammatory bowel disease had had a colorectal endoscopy within the previous 2 years; had two or more first-degree relatives with colorectal cancer; or had a medical condition that would preclude benefit from screening.
Random Assignment and Invitation for Screening
People who answered that they were probably or definitely not interested in screening were not contacted again. Eligible respondents who indicated that they would definitely or probably undergo screening sigmoidoscopy if it were offered to them were assigned randomly to the intervention or control group in a 1 : 1 ratio. Random assignment was performed in each center by the local coordinating unit with the use of a computer-generated allocation algorithm. In Biella, Genova, and Milano, subjects were assigned randomly on an individual basis; in Milano the algorithm automatically assigned spouses to the same arm of the trial. In Arezzo, Rimini, and Torino, a cluster randomization was adopted, with the unit of randomization being the physician. In these centers, general practitioners were stratified according to the proportion of eligible respondents and then randomized in a 1 : 1 ratio within each class of response rate (ranging from 5% to 35%), based on a computer-generated random number sequence.
Subjects assigned to the control group were not contacted. Subjects assigned to the intervention group were sent a personal invitation letter, signed by their physician (or by the study coordinator, if the physician refused), with a prescheduled appointment for a sigmoidoscopy. A leaflet containing a brief description of the procedure and mentioning its possible side effects was also included. Recipients were asked to call the screening center to confirm, reschedule, or cancel their appointment. Those who agreed to a test date were asked to visit their physician or the screening center to obtain an enema kit. A reminder letter was mailed to all individuals who did not respond to the first invitation letter. In Rimini and Torino, a second invitation was sent to those who did not respond to the first invitation and to the reminder after 12 months.
Screening Procedure
Screening was undertaken by specialist gastroenterologists in hospital endoscopy units. Bowel preparation was limited to a single enema (133 mL of 22% sodium phosphate) that subjects were asked to self-administer at home 2 hours before the test. No dietary restriction was recommended. All patients gave written informed consent for the screening procedure before it was done. A 140-cm colonoscope was used in all centers except Genova, where a sigmoidoscope was used. The aim of the examination was to advance the endoscope beyond the sigmoid-descending colon junction under adequate bowel preparation. No sedation was offered, but it could be administered if the endoscopist thought it was necessary. The endoscopist recorded on a standard form information about adequacy of bowel preparation, reach of the scope, characteristics of detected lesions, visualization of other findings, and occurrence of immediate complications. If the sigmoidoscopy could not be performed because of inadequate bowel preparation, the screenee was invited to repeat the test at a later date.
After the examination, the endoscopist gave each patient a letter explaining the results and reminding the patient of the limitations of the procedure already mentioned in the leaflet. Individuals were advised to contact their physician or the endoscopy unit if they noticed rectal bleeding or experienced abdominal pain during the first few days after the procedure. Immediately after the exam, all screenees were asked to complete a short questionnaire administered by a research assistant independent of the endoscopy staff, asking about the degree of pain and embarrassment experienced during the test. Patients were asked by the interviewer to indicate which of four mutually exclusive statements best described their experience of pain: only mild discomfort; I thought it would be worse; I hope it will not be necessary to repeat the test again; it was the most severe pain I have ever experienced. Embarrassment was also rated on a four-level scale: unacceptable, severe, moderate, mild.
Management of Polyps and Referral for Colonoscopy
The study protocol stipulated that polyps 5 mm or smaller should be removed during sigmoidoscopy, using the cold snare technique (1920). Diathermy snare was not recommended because it has been associated with an increased risk of complications (2122) and because the heating effect of electro-coagulation may render the specimens difficult to examine (20). Screenees who had one distal polyp larger than 5 mm, or inadequate bowel preparation and at least one polyp, or invasive colorectal cancer were referred for colonoscopy. In a few cases the referral to colonoscopy was made by the endoscopist, based on his or her clinical judgement. Any removed polyp was analyzed by histologic examination. Colonoscopy was also indicated, on the basis of histologic examination of small polyps (5 mm) excised at sigmoidoscopy, for subjects with three or more adenomas, with one villous or tubulovillous adenoma [villous component >20% (23)], or with one adenoma with severe dysplasia. When the colonoscopy could not be completed due to patient discomfort, a double-contrast barium enema was indicated; when that could not be achieved due to unsatisfactory bowel preparation the patient was invited to undergo a repeat colonoscopy within 6 months.
Criteria for colonoscopic surveillance.
A follow-up colonoscopy was scheduled at 3 years for all patients who, after being referred for colonoscopy, were found to have colorectal cancer or "high-risk" adenomas (i.e., one adenoma of 10 mm an adenoma with severe dysplasia, an adenoma with villous component >20%, or three or more adenomas of any type). Subjects with negative sigmoidoscopy or with other types of polyps were discharged and offered no further follow-up.
Histologic evaluation. Polyps and cancers were classified according to World Health Organization criteria (23). Cancer was defined as the invasion of malignant cells beyond the muscularis mucosae. To avoid inappropriate bowel surgery, slides of malignant adenomas were reviewed by two pathologists (a consensus diagnosis was reached in case of discordance) to assess features associated with low risk of lymph nodal metastases (24) (i.e., low-grade, well, or moderately differentiated lesions; resection margin free of cancer; neoplastic embolization absent). In addition, slides of all cancers and of a sample of adenomas with severe dysplasia were reviewed blindly by one pathologist from the U.K. group that was conducting the parallel flexible sigmoidoscopy screening trial (Professor G. Williams), and one pathologist from the Italian group (Dr. M. Risio). The classification of discordant cases was based on the majority diagnosis including the original diagnosis.
Statistical Analysis
Polyp size was classified according to the diameter of the largest polyp recorded by the endoscopist. For the statistical analysis the largest or the most advanced polyp detected in each individual was used. Polyps detected at screening sigmoidoscopy, including those lesions located beyond the sigmoid-descending colon junction, were defined as distal polyps.
A complete colonoscopy was reported if the cecum could be visualized or, in the case of failure, when a second colonoscopy performed within 6 months of the previous one was able to visualize the cecum. The combined results of the two colonoscopies were included in the analysis. Data concerning the performance of colonoscopy, in terms of completion rate and complications, are reported only for those examinations performed before cancer surgery because colonoscopies performed after bowel resection may be influenced by clinical and technical factors that are not directly relevant to a screening context.
Chi-square tests were used to test for statistical significance in comparisons of proportional parameters. Relative risks (RRs) with 95% confidence intervals (CIs) computed on the basis of the normal approximation of the log (RR) distribution using the Taylor series-derived variance of log (RR) (25) were calculated to estimate differences in the characteristics of detected lesions by sex and age. All statistical tests were two-sided and were considered statistically significant at P<.05. In this interim report, we did not adjust for the hybrid randomization design in the statistical analysis. As a consequence, the actual P values and 95% CIs may be slightly larger than those presented here. However, the differences are likely to be small, given the large number of clusters and their small size.
We planned to enroll 40 000 eligible respondents and to achieve an attendance rate of about 70% in the screening arm. Assuming the age-specific incidence rates for the period 19881992, as reported in the local cancer registries (26), and a weighted lead time of screen-detected colorectal cancer (weighted average) of 3.5 years, the targeted sample size would give 80% power to detect a 21% reduction in incidence of colorectal cancer in the intervention group at 6 years that is statistically significant at the 5% level using a one-sided test (27). A statistically significant reduction in mortality cannot be detected before 11 years of follow-up.
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RESULTS |
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We mailed the interest-in-screening questionnaire to 236 568 people, of whom 56 532 (23.9%) replied (Fig. 1). Of the 43 010 (18.2%; range 14.8%24.8% in the six trial centers) respondents who said they would definitely or probably attend screening if offered it, 4838 (11.2%) were found to be ineligible. Of the 13 522 respondents who said they were not interested, 1244 (9.2%) were found to be ineligible (Fig. 1
). In total, 34 292 people were assigned randomly to one of the two arms (Fig. 1
). Cluster randomization (i.e., by physician) was used in three centers contributing 17 602 patients from the rosters of 507 physicians; the remaining 16 690 patients were randomized individually. Recruitment began in October 1995 and was completed in April 1999.
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Of the 17 148 subjects randomly assigned to the intervention arm, 9999 (58.3%) actually attended the endoscopy unit to receive a sigmoidoscopy exam (Fig. 1). Of the 9558 subjects who indicated in the interest-in-screening questionnaire that they would definitely have the test if invited, 6713 (70.2%) attended; of the 7590 who responded that they would probably have the test if invited, 3286 attended (43.3%) (P<.001).
Attendance rates in the different centers, except for Genova, ranged from 54.3% to 64.1%. Overall attendance in Genova (65.5%) was higher than in the other centers because, starting in December 1996, only subjects who responded that they would definitely have the test if invited were randomized at that center. Indeed, low compliance was observed in Genova during the initial recruitment period among subjects who responded that they would probably have the test if invited; therefore, such subjects were no longer randomly assigned. The second invitation, which was mailed after 12 months to subjects who did not respond to the first invitation and to the mailed reminder, resulted in a 5.8% absolute increase in the attendance rate in Rimini and Torino.
The sigmoidoscopy could be completed (i.e., reached beyond the sigmoid-descending colon junction, under adequate bowel preparation) on a single occasion in 7977 (79.8%) of the 9999 attenders. Among the remaining 2022 subjects, the examination was terminated because of pain or bowel adhesions in 749 subjects (37.0%), and unsatisfactory bowel preparation resulted in only partial visualization of the colonic mucosa in another 650 subjects (32.1%). Of these 1399 (749 + 650) patients, 119 were referred for colonoscopy because a polyp was detected in the segments examined and the other 1280 subjects were not asked to return for subsequent tests. The other 623 subjects (30.8%) had bowel preparation that was so inadequate that no segment of the bowel mucosa could be visualized; these subjects were all offered new tests, and 535 (85.9%) attended. The examination was completed to the descending colon in 468 of these individuals. Therefore, a complete sigmoidoscopy to the distal descending colon was achieved in 8445 (7977 + 468) of the 9999 attenders (84.5%).
Out of 9999 screenees, 9911 (7977 + 749 + 650 + 535) were actually examined, and 88 were not. Of the 9911 subjects who were examined, there was no evidence of pathology in 8166 (82.4%) (Fig. 2). For 152 additional subjects, a tissue specimen (
5 mm) was removed and classified by the pathologist as normal for 96 subjects; the tissue was missed or the sample was inadequate in the other 56 subjects. Another 741 subjects had low-risk polyps 5 mm or smaller (i.e., a hyperplastic polyp in 306 subjects and a tubular adenoma in 435 subjects). An additional 20 patients (19 with clinical evidence of colorectal cancer and one following perforation) were referred for surgery immediately after sigmoidoscopy. The remaining 832 subjects were referred for colonoscopy, and 775 (93.1%) of those attended (Fig. 2
). In 638 of the 832 subjects (Fig. 3
), the colonoscopy was indicated based on the characteristics of distal polyps; in 119 cases, referral for colonoscopy followed detection of a small polyp during an incomplete sigmoidoscopy (this policy was adopted to avoid a third endoscopic procedurecolonoscopyin those people in whom high-risk polyps were detected at the second sigmoidoscopy); and in 75 cases, referral was based on the clinical judgement of the endoscopist (e.g., presence of five or more hyperplastic polyps, blood in the lumen of the intestine, patients self-reported worry about abdominal symptoms, family history of colorectal cancer, concern about safety of polypectomy for patients on anticoagulants).
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Yield of Benign Lesions
The prevalence of distal polyps among the 9911 subjects who received sigmoidoscopy was 17.6%. Multiple polyps were detected in 477 (4.8%) subjects (279 had two polyps, and 198 had three or more). Distal adenomas were detected in 1070 (10.8%) subjects (range, 5.9%14.7% across the trial centers) (Table 2). Men showed a statistically significantly higher prevalence than women of non-neoplastic polyps (RR = 2.08, 95% CI = 1.71 to 2.53), adenomas (RR = 1.64, 95% CI = 1.46 to 1.85), and colorectal cancer (RR = 2.30, 95% CI = 1.22 to 4.36). Distal adenomas were detected more frequently among subjects 60 years of age and older than among those younger than 60 years (RR = 1.15, 95% CI = 1.03 to 1.29). Subjects 60 years of age and older also showed a higher prevalence of advanced adenomas (
10 mm, with villous component >20%, or with high-grade dysplasia) than those younger than 60 years (RR = 1.28, 95% CI = 1.04 to 1.58). The proportion of adenomas with severe dysplasia or with villous component greater than 20% also increased with polyp size: it was 9.8% for adenomas smaller than 10 mm and 45.8% (P<.001) for adenomas 10 mm or larger.
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There were a total of 54 subjects with colorectal cancer (Table 4): 47 with a distal cancer, identified among the 9911 subjects who underwent sigmoidoscopy (19 immediately referred for surgery and 28 referred for colonoscopy), and seven among the 747 patients without distal cancer who were referred for colonoscopy. One patient with distal colorectal cancer also harbored a synchronous malignant lesion in the proximal colon, another harbored two tumors in the sigmoid colon, and a third had two tumors at the splenic flexure. Thus, together these patients contained 57 malignant colorectal tumors: 48 were detected at sigmoidoscopy (18 in the rectum, 28 in the sigmoid colon, and two in the descending colon), and nine were detected at colonoscopy (three at the splenic flexure, one in the transverse colon, one at the hepatic flexure, three in the ascending colon, and one in the cecum). Twenty-six of the colorectal cancers were malignant adenomas. The detection rate for colorectal cancer was 5.4 per 1000 (54/9911), and for 29 of the 54 patients (54%) the colorectal cancer was classified as Dukes A or was judged to be localized. Indeed, treatment was limited to endoscopic excision in 11 of 26 cases of malignant adenomas.
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Three people developed complications requiring hospitalization. Among the 9911 subjects who underwent sigmoidoscopy there was one perforation (0.1 per 1000), and among the 775 subjects who underwent colonoscopy there was one perforation and one episode of bleeding following polypectomy (both 1.3 per 1000). In addition, one patient was brought to an emergency room with a peritonitis-like reaction the day after screening sigmoidoscopy, although his symptoms disappeared within a few hours; two patients developed glutaraldehyde colitis; one patient had an allergic reaction to latex gloves; two patients, both receiving anti-epileptic treatment, suffered seizures that required medical treatment; 17 patients had self-limited bleeding following polypectomy (10 at sigmoidoscopy and seven at colonoscopy); 49 patients complained of mild vagal reactions (nausea, feeling faint, or feeling dizzy) (42 at sigmoidoscopy and seven at colonoscopy); and 24 patients (eight at sigmoidoscopy and 16 at colonoscopy) complained of abdominal pain. Overall, minor self-limited complications occurred in 0.6% (60/9911) of patients who had sigmoidoscopy and in 4% (30/775) of patients who received colonoscopy.
Patients Experience
Of the 9911 people who underwent sigmoidoscopy, 9394 (94.8%) completed the short questionnaire administered immediately after the test. Of these, 60.4% reported mild discomfort and 22.9% reported that they found the test to be less painful than expected. Only 2.0% described the pain as the most severe they had ever experienced. Women rated the pain as severe ("I hope it will not be necessary to repeat the test again" or "It was the most severe pain I have ever experienced") more often than men (16.0% versus 7.6 %; P<.001). Only 5.1% of the screenees found the test more than mildly embarrassing. This proportion was similar for men and women.
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DISCUSSION |
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The trial protocol was similar to the one adopted in the U.K. trial (17). The main differences concerned the randomization procedure and the criteria for colonoscopy referral. Cluster randomization (i.e., using the physician as the unit of randomization) was adopted in three of the six Italian centers to reduce the probability of contamination in a context of open-access (i.e., through the physician) endoscopy. In the U.K. trial (17), a household-based randomization procedure was adopted.
The criteria for colonoscopy referral were the same in the Italian and U.K. trials, except for the size of distal polyps and the management of subjects with distal polyps detected at incomplete sigmoidoscopy. In Italy, all subjects with distal polyps larger than 5 mm were referred for colonoscopy to increase the sensitivity of screening for advanced proximal neoplasia, whereas in the United Kingdom only patients with distal polyps larger than 10 mm were referred for colonoscopy. If the same criteria for "high-risk" distal lesions had been adopted in Italy as in the United Kingdom, 486 of the 9911 screenees (4.9%) would have been referred for colonoscopy, instead of 832 (8.4%). Approximately 49% of this 3.5% difference (i.e., 171 subjects) is attributable to the different threshold of polyp size. Also, the Italian trial, but not the U.K. trial, included the option of referring people with incomplete sigmoidoscopy for colonoscopy when detecting any distal polyp, and this difference accounted for about 34% of the additional referrals. In the remaining Italian cases, referral for colonsocopy was based, as in the U.K. trial, on the judgement of the endoscopist. Thus, adopting the 10-mm size threshold would have resulted in 171 fewer colonoscopy referrals at baseline. Of these 171 patients, 155 underwent colonoscopy, and advanced proximal lesions were detected in three (1.9%). This prevalence is similar to that among men and women without distal polyps who underwent colonoscopy screening (39). By contrast, advanced neoplasms were found in the proximal colon in 9.9% of patients with "high-risk" (according to the criteria adopted in the U.K. trial) distal adenomas. Therefore, the lower threshold size for distal adenomas used in the Italian trial does not appear to have considerably increased the sensitivity for "high-risk" proximal polyps.
The two-stage recruitment procedure used in all centers in the Italian trial (i.e., questionnaire to assess interest in and eligibility for screening followed by randomization of interested and eligible respondents) increased the attendance rate, which was about 58%, double the 29% uptake rate observed in a pilot study in Torino (28). However, although this approach increased the study efficiency, it decreased the degree of coverage of the target population, at least as compared with the pilot study. The 58% attendance rate among the 16% of eligible respondents who expressed an interest in screening resulted in the enrollment of about 9% of the source population.
We cannot exclude the possibility that these response rates reflect self-selection of subjects who might have a risk of colorectal cancer different from that in the general population. Analyses of people recruited in Torino and Genova (data not shown) indicate that people with higher levels of education had a higher response rate to the questionnaire than people with lower levels of education. A higher incidence of colorectal cancer has already been documented in people with higher levels of education compared with people with lower levels of education (29). However, this selection process should not affect the validity of the trial, because only eligible responders were entered into the trial. Also, there is no apparent biologic reason for the proportional benefit of screening to be different among subjects who have different risks of colorectal cancer.
Because all subjects targeted for recruitment will be followed up for colorectal cancer incidence and mortality through regional registries of hospital discharge records, death certificates, and local cancer registries, we will be able to compare baseline risks of colorectal cancer among those who did not respond to the mailed questionnaire with risks among those who were allocated to the control group of the trial. Therefore, we will be able to assess the impact of the low response rate to the questionnaire (23.9%) on the generalizability of the trial findings. Moreover, because the response rate to the mailed questionnaire was similar to the observed attendance rate in the pilot phase of the trial (28), respondents are likely to be representative of the individuals who would participate in a colorectal cancer screening program in Italy.
It should also be noted that no mass-media campaign could be implemented in the trial context, which may partially explain the low response rate to the questionnaire. However, the cumulative response rate may be more relevant for evaluating the impact of a screening strategy based on a single test than compliance with each single invitation. The 5.8% absolute increase in the proportion of attenders observed in two trial centers (Rimini and Torino) following an additional invitation mailed to nonresponders after 1 year indicates that repeated invitations might represent an effective strategy to extend population coverage.
The high detection rate for colorectal cancer may be partially attributable to the selective enrollment of a high proportion of subjects who are at increased risk for the disease. However, it might also reflect the magnitude of the anticipation of the cancer diagnosis achievable through sigmoidoscopy. Walter and Day (31) suggest that the ratio of prevalence to incidence can be considered an estimate of the mean sojourn time. Based on the observed prevalence in the trial and on incidence data available from the cancer registries in the study areas (30), we estimate this ratio to be 4.6, suggesting that, in general, the approach adopted by the SCORE trial for colorectal cancer screening (sigmoidoscopy and total colonoscopy for subjects with high-risk distal adenomas) detects many early-stage malignant lesions. The high proportion of malignant adenomas, which made up 26 of the 54 (48%) screen-detected colorectal cancers in our study, supports this hypothesis.
The observed detection rate is consistent with those seen in studies comparing sigmoidoscopy and fecal occult blood testing (3234). Moreover, the detection rate of adenomas 10 mm or larger or with a villous component of more than 20% (3.7%) was approximately four times higher than in studies of fecal occult blood testing screening (using either guaiac or immunochemical tests) (3537). This finding is consistent with the expected impact of screening on colorectal cancer incidence because the estimated conversion rate of these lesions is high (13,38).
The need to repeat sigmoidoscopy in cases of unsatisfactory bowel preparation is a crucial problem because of the possibility of undetected lesions and the unwillingness of most patients to undergo a second sigmoidoscopy examination. About half of the subjects with incomplete sigmoidoscopy due to unsatisfactory bowel preparation were not invited to repeat the test. It appears that physicians offered a repeat sigmoidoscopy examination only when the reach of the instrument was so limited that they could not be confident that important lesions had not been missed. Indeed, the median reach of the instrument in these cases was 45 cm, and no lesion was detected in the segments examined (data not shown). Moreover, some patients may well have been unwilling to repeat the whole screening procedure. In our pilot study (28), about two thirds of subjects with inadequate bowel preparation who were offered a new test date did not attend.
Colonoscopy could not be completed to the cecum in about 25% of the patients. The lower completion rate in our screening setting, as compared with that reported in other studies (33,40), may be explained by a different attitude of the doctors and patients in our study. To minimize the risk associated with the procedure, the endoscopists participating in our study tended to avoid administering sedation and to interrupt the examination if patients complained of excess pain. That this approach likely did not lead to missed cancers seems to be supported by the fact that no proximal neoplasms were detected among the 76 patients with incomplete colonoscopy who underwent a double-contrast barium enema. On the other hand, asymptomatic patients may have been less motivated to tolerate procedure-related disturbances.
The acceptability of sigmoidoscopy was satisfactory, with only 2% of the screenees rating the pain associated with the procedure as severe, although the test was routinely performed without sedation. Overall, minor, self-limited complications occurred in about 0.6% of the subjects who received sigmoidoscopy and about 4% of those who received colonoscopy. The rates of severe complications compare favorably with those observed in other studies of both examinations (4145), especially given that 89% of the subjects in our trial who underwent colonoscopy had at least one polyp removed (data not shown). A recent prospective study (46) suggested that the previous reports, which were based mainly on patient record reviews, might have underestimated the complication rate. In that study, only 15% of the complications reported by patients interviewed 30 days after outpatient colonoscopy were known before the interview. Immediate complications were systematically recorded in our study for all patients before they left the endoscopy unit. Information on late complications was obtained from physician and endoscopist reports and by directly contacting all patients referred for surveillance. We cannot exclude the possibility that, in some cases, additional minor complications that did not require hospitalization or referral to hospital outpatient clinics occurred in the days following screening.
A high variability was observed across the trial centers, when considering a series of performance indicators (e.g., completion rates of sigmoidoscopy and colonoscopywhich ranged from 81.5% to 98.2% and from 51.8% to 87.1%, respectivelyand detection rates of distal and proximal adenomas, which ranged from 5.9% to 14.7% and from 3.5% to 21.6%, respectively). This variability suggests the need to implement quality-control procedures when planning to use sigmoidoscopy in a large-scale, population-based screening program. Minimum performance standards of endoscopic examinations should be established to achieve adequate levels of accuracy from these screening procedures.
In conclusion, the baseline results from the SCORE trial show that sigmoidoscopy can be an acceptable and safe screening strategy for colorectal cancer. The high yield of advanced lesions and early colorectal cancer is consistent with the projected substantial impact of sigmoidoscopy screening on colorectal cancer incidence and mortality. The positive experience reported by attenders may contribute to enhance participation rates of screening programs in the future.
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APPENDIX |
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Local trial coordinators: P. Ghezzi (Centro Oncologico); T. Galli (Surgery Unit, Ospedale degli Infermi); A. Cardelli (Gastroenterology Unit, Ospedale degli Infermi, AUSL, Rimini).
Pathologists: V. Sforza (Pathology Unit, Centro Oncologico, Arezzo); M. Giudici (Pathology Unit, Ospedale degli Infermi, Biella); S. Bosari, G. Viale (Pathology Unit, European Institute of Oncology, Milano); P. Rinaldi (Pathology Unit, Ospedale degli Infermi, AUSL, Rimini); E. Berardengo (Pathology Unit, Ospedale S Giovanni Antica Sede, ASO S Giovanni Battista, Torino).
Endoscopists: D. Angioli, A. Agnolucci, P. Ceccatelli (Gastroenterology Unit, Ospedale S Donato, Arezzo). G. Malfitana, A. Azzoni, F. Ferrero (Gastroenterology Unit, Ospedale degli Infermi, ASL 12, Biella); V. Pugliese (Unit of Gastroenterology and Nutrition, National Institute for Cancer Research and Department of Oncology Biology and Genetics, University of Genova); F. Munizzi, S. Saccomanno (Unit of Gastroenterology and Nutrition, National Institute for Cancer Research, Genova); S. Bargiggia (Endoscopy Unit, Sacco Hospital, Milano); C. Gerosa (Unit of Gastroenterology, S Carlo Hospital, Milano); G. Minoli (Unit of Gastroenterology, Valduce Hospital, Como); R. Penagini (Endoscopy Unit, Policlinico Hospital, Milano); A. Prada (Unit of Gastroenterology, General Hospital, Rho); E. Viale (Endoscopy Unit, S Raffaele Hospital, Milano); G. Fiori (Unit of Gastroenterology, European Institute of Oncology, Milano); A. Arrigoni, A. Bertone, M. Cavallero, C. Gemme, M. Pennazio, M. Spandre (Gastroenterology Unit, Ospedale S Giovanni Antica Sede, ASO, S Giovanni Battista, Torino); G. Babando, F. Coppola, M. Fracchia, G. Galatola, A. Pera (Gastroenterology Unit, Ospedale Mauriziano "Umberto I", Torino).
Research assistants: G. Genta (Fondo "E Tempia," ASL 12, Biella); L. Marzona, M. Lotti (Surgery II, European Institute of Oncology and University of Milano, Milano); O. Giuliani (Gastroenterology Unit, Ospedale degli Infermi, AUSL, Rimini); D. Brunetti, B. Forlai (Unit of Epidemiology, CPO, Piemonte, ASO S Giovanni Battista, Torino).
Data managers: M. Forlai (Unit of Epidemiology, CPO, Piemonte, ASO, S Giovanni Battista, Torino); M. Carloni, C. Crotti (Surgery II, European Institute of Oncology and University of Milano); S. Bartolini (Gastroenterology Unit, Ospedale degli Infermi, AUSL, Rimini); A. Marutti (Fondo "E Tempia," ASL 12, Biella); A. M. Nicora (Unit of Clinical Epidemology and Trials, National Institute for Cancer Research, Genova); L. Frasconi (Centro Oncologico, Arezzo).
Database design: M. Demaria (Epidemiology Unit, ASL5, Grugliasco, Torino).
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