Objective Suboptimal adenoma detection rate (ADR) at colonoscopy is associated with increased risk of interval colorectal cancer. It is uncertain how ADR might be improved. We compared the effect of leadership training versus feedback only on colonoscopy quality in a countrywide randomised trial.
Design 40 colonoscopy screening centres with suboptimal performance in the Polish screening programme (centre leader ADR ≤25% during preintervention phase January to December 2011) were randomised to either a Train-Colonoscopy-Leaders (TCLs) programme (assessment, hands-on training, post-training feedback) or feedback only (individual quality measures). Colonoscopies performed June to December 2012 (early postintervention) and January to December 2013 (late postintervention) were used to calculate changes in quality measures. Primary outcome was change in leaders’ ADR. Mixed effect models using ORs and 95% CIs were computed.
Results The study included 24 582 colonoscopies performed by 38 leaders and 56 617 colonoscopies performed by 138 endoscopists at the participating centres. The absolute difference between the TCL and feedback groups in mean ADR improvement of leaders was 7.1% and 4.2% in early and late postintervention phases, respectively. The TCL group had larger improvement in ADR in early (OR 1.61; 95% CI 1.29 to 2.01; p<0.001) and late (OR 1.35; 95% CI 1.10 to 1.66; p=0.004) postintervention phases. In the late postintervention phase, the absolute difference between the TCL and feedback groups in mean ADR improvement of entire centres was 3.9% (OR 1.25; 95% CI 1.04 to 1.50; p=0.017).
Conclusions Teaching centre leaders in colonoscopy training improved important quality measures in screening colonoscopy.
Trial registration number NCT01667198.
- COLORECTAL ADENOMAS
- COLORECTAL CANCER SCREENING
- CLINICAL TRIALS
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Significance of this study
What is already known on this subject?
Suboptimal adenoma detection at colonoscopy is associated with increased risk of interval colorectal cancer and colorectal cancer death.
Interventions targeting endoscopist performance have been generally ineffective for improving adenoma detection rates.
One small study performed at single academic institution showed adenoma detection rate improvement with training.
What are the new findings?
Dedicated Train-Colonoscopy-Leaders course significantly improved adenoma detection rate, proximal adenoma detection rate and non-polypoid lesion detection rate in screening colonoscopy.
The training of screening centre leaders in teaching high quality colonoscopy changed their own practice and had also significant effect on overall centre performance.
The Train-Colonoscopy-Leaders course had sustained effect on colonoscopy performance over 1.5 years.
How might it impact on clinical practice in the foreseeable future?
Developed training curriculum may help to improve adenoma detection rate and non-polypoid lesion detection rate at colonoscopy.
During recent years, several studies have shown that important patient outcome measures such as interval cancer rates after screening colonoscopy or mortality after cancer surgery are related to quality of hospitals and individual physicians.1–3 However, there is a lack of high quality studies investigating the effect of quality improvement interventions on patient outcome measures.
Screening colonoscopy is widely used for prevention and early detection of colorectal cancer (CRC).4 High quality colonoscopy achieving accurate detection and removal of adenomas is considered the key to screening efficacy.5–7 Professional societies recommend that endoscopists measure quality indicators such as adenoma detection rate (ADR), caecal intubation rate (CIR) and colonoscope withdrawal time.6 ,7 We have previously shown that an individual endoscopist's ADR is an independent predictor for interval cancer after screening colonoscopy.1 Recently, a large US study confirmed this association and expanded it to include CRC death.3 Thus, adenoma detection is of paramount importance for the success of CRC screening programmes. However, it has been uncertain how to improve ADR in endoscopists with suboptimal performance.
Simple interventions, such as involvement of a trainee or video recording of the colonoscopy,8–11 or an institutional policy to keep colonoscope withdrawal time above the recommended limits12 ,13 has not shown significant improvements of ADR.14 It has been proposed that improving ADR requires a multifaceted change15 ,16 in the knowledge, skills and motivation of endoscopists. Audit and feedback of screening colonoscopy quality indicators have proven to be moderately effective in improving adenoma detection for some but not all endoscopists,17 ,18 and an educational intervention improved adenoma detection of gastroenterologists at one academic institution.19 Multicentre, comparative studies on the effect of quality improvement strategies to increase ADR are lacking.
The present large-scale randomised trial investigates the effect of a hands-on training course for leading colonoscopists at screening centres to improve their adenoma finding skills and overall screening centre performance compared with a simple audit and feedback.
This was a multicentre, randomised (1:1 ratio), single-blind, parallel-group study performed in 40 centres of the National Colorectal Cancer Screening Programme (NCRCSP) in Poland.
The NCRCSP is a colonoscopy-based programme involving asymptomatic subjects 40–66 years of age.20 ,21 Each participating centre has one dedicated leading colonoscopist who is responsible for coordination and supervision of the programme locally (screening centre leader; usually formal head of the endoscopy unit who underwent training in administration of the screening centre when entering the NCRCSP). We compared the effect of two educational interventions on ADR of these screening centre leaders and all endoscopists working at their centres.
The study was conducted in four phases: (i) preintervention phase, (ii) intervention phase, (iii) early postintervention phase and (iv) late postintervention phase. In the preintervention phase (1 January 2011 to 31 December 2011), colonoscopy quality indicators were extracted from the NCRCSP database. Centre leaders were unaware of the study during this phase. At the start of the intervention phase, screening centre leaders were randomly assigned to either a designated educational intervention (‘Train-Colonoscopy-Leaders course’ (TCL)) or to routine audit and feedback. Both interventions started on 1 June 2012 and the TCL phase was completed by 30 August 2012. Quality indicators were measured in the early postintervention phase (1 June 2012 to 31 December 2012; leaders were aware of being closely monitored) and in the late postintervention phase (1 January 2013 to 31 December 2013; leaders were unaware of being closely monitored) using the same method.
The study was approved by the Research Ethical Committee of the Maria Sklodowska-Curie Memorial Cancer Centre and Institute of Oncology, Warsaw, Poland (#17/2012). Written informed consent was obtained from all screening participants entering the NCRCSP and all screening centre leaders. The study was registered with ClinicalTrials.gov, NCT01667198.
Endpoints and definitions
Study endpoints were differences between preintervention and postintervention colonoscopy quality indicators in the two arms using all colonoscopies recorded in the NCRCSP database. The screening colonoscopy procedures have been described previously.20 Findings at screening colonoscopy were categorised on the basis of the most advanced lesion identified.20 Polyps that were not removed or retrieved were categorised as non-neoplastic and not taken into account when calculating ADR.
The primary study endpoint was the change in screening centre leaders’ ADR from preintervention to early postintervention phase. ADR was defined as the proportion of screened subjects in whom at least one adenoma was identified.7 Predefined secondary endpoints for the early postintervention phase were proximal ADR (defined as ADRs proximal to the splenic flexure), non-polypoid lesion detection rate and CIR, all of which were evaluated for both screening centre leaders and for the centres. All these endpoints were subsequently measured for the late postintervention phase compared with the preintervention phase. CIR was defined as the proportion of colonoscopies in which the endoscope tip reached proximal to the ileocaecal valve and the entire caecum was visualised.7 Non-polypoid lesions were defined as lesions 5 mm or larger which were depressed, completely flat or elevated less than 2.5 mm.22
All screening centre leaders who performed at least 30 NCRCSP screening colonoscopies in 2011 and achieved an ADR lower than 25% were eligible for the study (40 out of 93 centres in the NCRCSP) unless they discontinued participating in the NCRCSP in 2012.
Randomisation and masking
In May 2012, eligible screening centre leaders were randomly assigned in a 1:1 ratio to the TCL group or the feedback group. Randomisation lists were computer-generated and stratified by screening centre leader baseline ADR category (<11%, 11%–14.9%, 15%–19.9%, 20.0%–24.9%).1 Participating screening centre leaders were informed that they were participating in a trial testing two different training programmes dedicated for trainers but were not informed about trial aims and endpoints. All other colonoscopists were not informed about the study but were aware of being monitored as a routine part of the NCRCSP. In the year 2013 (late postintervention phase), all colonoscopists (including screening centre leaders) were aware only of being monitored as a routine part of the NCRCSP.
Screening centre leaders randomised to the feedback group received (by email and surface mail) feedback on their individual preintervention screening colonoscopy quality indicators along with aggregated results for the entire screening centre. The individual results were presented in a table to enable comparison with anonymised results of all endoscopists who performed at least 30 colonoscopies within the NCRCSP (see online supplementary appendix 1). In addition, a link to a webpage containing data on individual and overall colonoscopy quality indicators from the last 4 years of the NCRCSP was provided. The email feedback was provided also after early postintervention phase.
Screening centre leaders randomised to the TCL group were invited to participate in a TCL course consisting of three phases: (i) pretraining assessment, (ii) hands-on training and (iii) post-training evaluation and feedback (see online supplementary appendix 2). The underlying hypothesis of the training intervention was to train the leaders on how to teach high quality colonoscopy and thereby to facilitate self-development and disseminate high standards of care.
The pretraining assessment phase involved a 2-h visit held in June and July 2012 at each screening centre. It used an environmental assessment checklist to find reasons for suboptimal performance. After the pretraining visit, local endoscopy nurses observed 10 consecutive colonoscopies performed by the screening centre leader to assess patient discomfort (using a 100 mm visual analogue scale) and withdrawal technique.23 Local endoscopy nurses were trained to assess withdrawal technique and discomfort by the study team. Prior to starting the hands-on training phase, the TCL trainers were subject to a 2-day intensive training course by UK trainers (JA, RV) providing them with techniques used in skills improvement, training the trainer and leadership training programmes developed in the UK. During these 2 days, the focus was on using techniques known to change professional practice.24 The hands-on training phase consisted of two half-a-day courses at the NCRCSP coordinating centre. The hands-on training course included at least one session for each participating screening centre leader playing the role of a trainee (performing colonoscopy) and at least one as a trainer (supervising colonoscopy), observed by the other course participants (by video streaming). The TCL trainers from the Institute of Oncology facilitated discussion on the training episode among all participants. The schedule of each course was modified to address issues identified in the pretraining assessment. Six to seven screening colonoscopy leaders were trained during each training session (held between July and August 2012).
The post-training evaluation encompassed evaluation of the screening centre leaders’ colonoscopy performance (extracted from the database) during the first 30 procedures following the hands-on training course, and a further nurse assessment of 10 consecutive colonoscopies identical to that done in the pretraining phase. Finally, all leaders in the TCL group received feedback on individual performance along with aggregated results for the entire screening centre and access to the same webpage as leaders in the control group. The email feedback was provided also after early postintervention phase. According to protocol of the study, we had not planned to assess whether leaders extended training to other colleagues within the screening centre. Upon reviewers’ request, we have performed a brief telephone survey among leaders asking whether they have extended training to their colleagues.
Power estimates and statistical analyses
We considered an absolute ADR improvement of 3% in the screening centre leaders randomised to the TCL group compared with 1.5% in those randomised to the feedback group17 as clinically meaningful to detect. A sample size of 34 screening centre leaders provided 80% power to detect a mean difference in ADR improvement of 1.5% with an estimated SD of 1.5% and a two-sided significance level (α) of 0.05. We planned to include 40 leader colonoscopists to take account of compliance with the study.
For the primary endpoint, we used a generalised linear mixed effects model with random colonoscopists and colonoscopists’ specific study phase effects, and fixed effects for the study group, phase, study group by phase interaction, and patient age and sex.25 A generalised linear mixed effects model allows analysing changes in colonoscopists’ performance over time treating them as a random sample from wider population and incorporating the possible correlation among outputs of participants examined by the same colonoscopists. The model allowed expressing the change in ADR at the participant level using ORs with corresponding 95% CIs. The OR for the interaction term reflects an excess in the OR of adenoma detection during the postintervention phases versus the preintervention phase in the TCL compared with the feedback group. Similar models were fitted for the secondary endpoints, including all the analyses comparing late postintervention phase and preintervention phase. Continuous variables (withdrawal technique scores, withdrawal time and patient pain scores) were checked for normality and compared using appropriate parametric or non-parametric tests. A p value of <0.05 was considered statistically significant. All reported p values are two-sided and not adjusted for multiple testing. The analyses were performed using Stata Statistical Software V.12 (Stata Corporation, College Station, Texas, USA).
Of the 40 screening centre leaders enrolled and randomised in a 1:1 ratio, one in each group was excluded due to consent withdrawal or lack of participation in the NCRCSP in 2012. Furthermore, in 2013, one screening centre leader in each group left the centre. Thus, all analyses comparing early postintervention phase and preintervention phase include 38 endoscopist leaders and their centres, whereas analyses comparing late postintervention phase and preintervention phase include 36 endoscopist leaders and 38 centres (figure 1). Data analyses are based on 24 582 colonoscopies performed by endoscopist leaders (10 983 in the preintervention, 6358 in the early postintervention, and 7241 in the late postintervention phase, respectively) and 56 617 colonoscopies performed in total at the participating centres throughout the trial phases (24 519 in the preintervention, 14 654 in the early postintervention and 17 454 in the late postintervention phase).
The intervention groups were well balanced with regard to baseline characteristics, colonoscopy experience and colonoscopy trainer experience (table 1). Screening centre leaders from both groups represented various medical specialties and types of practices, including academic, non-academic and private.
Screening centre leaders’ performance
The characteristics of the screenees and colonoscopy procedures by randomisation group and study phase are summarised in table 2.
Early postintervention phase versus preintervention phase
As shown in figure 2, in the early postintervention phase, the mean ADR of screening centre leaders in the TCL group improved by 8.2% (from 17.4% to 25.6%) compared with 1.1% (from 18.5% to 19.6%) in the feedback groups, (absolute difference 7.1%). The mean proximal ADR and non-polypoid lesion detection rate of screening centre leaders in the TCL group improved by 5.5% and 3.0%, respectively, whereas they improved by 1.6% and deteriorated by 0.5% in the feedback group, respectively (table 2). In the generalised linear mixed effects models, participation in the TCL course was associated with significant ADR improvement (OR 1.61; 95% CI 1.29 to 2.01; p<0.001), proximal ADR improvement (OR 1.58; 95% CI 1.19 to 2.11; p<0.001) and non-polypoid lesion detection rate improvement (OR 2.78; 95% CI 1.53 to 5.05; p=0.001) as compared with the feedback group. The mean CIR of screening centre leaders did not differ between the groups (OR 1.03; 95% CI 0.56 to 1.90; p=0.92). The changes in the mean ADR were observed across all endoscopist specialties and types of screening facilities (see online supplementary table S3 and supplementary table S4 for the results of expanded model).
The changes in the above mentioned different detection rates were in line with results of the assessments by endoscopy nurses of 18 leaders in the TCL group (one centre leader was not assessed by nurses). Mean colonoscopy withdrawal technique significantly improved from 63.5 (±9.8) points to 68.2 (±7.8) points (p=0.004), whereas mean colonoscopy withdrawal time and mean pain scores remained unchanged (12.1±6.7 min to 12.5±9.0 min; p=0.54, and 18.4±17.2 mm to 12.8±10.8 mm; p=0.16, respectively).
Late postintervention phase versus preintervention phase
As shown in figure 2, in the late postintervention phase the mean ADR of screening centre leaders in the TCL group deteriorated by 1.7% compared with early postintervention phase, but still remained improved by 6.5% compared with preintervention phase. In the feedback group, the mean ADR of screening centre leaders in the late postintervention phase improved by 1.2% compared with early postintervention phase and in total by 2.3% compared with preintervention phase. The absolute difference in the mean ADR improvement in the late postintervention phase compared with preintervention phase was 4.2% in favour of the TCL group. Results for proximal ADR and non-polypoid lesion detection rate in the late postintervention phase are shown in figure 2 and table 2.
In the generalised linear mixed effects models, participation in the TCL course was associated with sustained significant ADR improvement (OR 1.35; 95% CI 1.10 to 1.66; p=0.004) compared with the feedback group. The proximal ADR improvement (OR 1.33; 95% CI 0.98 to 1.80; p=0.07) and non-polypoid lesion detection rate improvement (OR 1.57; 95% CI 0.76 to 3.24; p=0.219) were no longer statistically significantly higher compared with the feedback group.
Screening centre performance
The characteristics of the screenees and colonoscopy procedures by randomisation group and study phase are summarised in table 3.
Early postintervention phase versus preintervention phase
The non-polypoid lesion detection rate improved by 1.5% (from 1.6% to 3.1%) and 0.2% (from 1.6% to 1.8%) in the TCL and feedback screening centres, respectively (for changes in other quality indicators, see table 3). In the generalised linear mixed effects models, participation of the leader endoscopist in the TCL course was associated with significant overall non-polypoid lesion detection rate improvement in the screening centre (OR 1.85; 95% CI 1.19 to 2.86; p=0.006), but not with ADR (OR 1.11; 95% CI 0.93 to 1.34; p=0.25) or proximal ADR (OR 1.17; 95% CI 0.91 to 1.50; p=0.21), or CIR (OR 0.86; 95% CI 0.58 to 1.29; p=0.47).
Late postintervention phase versus preintervention phase
As shown in figure 2, in the late postintervention phase, the mean ADR, proximal ADR and non-polypoid lesion detection rate of entire screening centres improved by 5.7%, 3.9% and 2.5%, respectively, in the TCL group as compared with 1.8%, 1.8% and 0.6%, in the feedback group, respectively.
In the generalised linear mixed effects models, participation in the TCL course was associated with significant ADR improvement (OR 1.25; 95% CI 1.04 to 1.50; p=0.017) and non-polypoid lesion detection rate improvement (OR 1.76; 95% CI 1.11 to 2.82; p=0.017) but not significant proximal ADR improvement (OR 1.23; 95% CI 0.97 to 1.55; p=0.082), as compared with the feedback group.
Brief telephone survey among screening centre leaders revealed that in the postintervention phase, 12 of them (63.2%) have already delivered the training in their centres, and the rest either had no candidates for training (15.8%), or plan to deliver training in the future (15.8%), or left the centre (5.3%). The mean ADR improved by 7.6% (from 18.2% to 25.8%) in the centres where training had been already delivered and by 3.1% (from 18.7% to 21.8%) in the remaining centres.
This is the first multicentre randomised comparative trial which shows that a dedicated Train-Colonoscopy-Leaders course improves important quality indicators in colonoscopy. The training of screening centre leaders in teaching high quality colonoscopy resulted in sustained change of their own practice and the performance of the centre as a whole.
Our training course represents a novel concept, aiming at multifaceted change in endoscopists’ skills and behaviours. The training was targeted at screening centre leaders with the aim of ensuring they appreciated the importance of high standards and providing them with a variety of techniques to train their teams on how to meet these standards. The training did focus on teaching high quality colonoscopy, withdrawal technique and non-polypoid lesion recognition, and on barriers for improvements in ADR at individual centres including aspects of organisation, workforce, communication, training and quality control. Our training course used techniques drawn from skills improvement, training the trainer and leadership courses developed in the UK. This methodology is based on key principles of adult learning and changing professional practice.24
Our primary study focus was leader's performance. We demonstrated that the TCL course resulted in a significant and sustained leader's ADR improvement; thereby, we confirmed that one of the best ways to learn is by teaching.26
The robust design of our study allowed us also to investigate the effect of training at the screening centre level. Indeed, in the late postintervention phase, we observed significant improvement in the ADR and non-polypoid lesion detection rate at the screening centre level. It was unrealistic to expect this to be evident in the early postintervention phase as it takes time to deliver the training to other endoscopists in screening centres. Our large-scale nationwide study results extend those of a recent single centre study showing ADR improvement with a short educational intervention.19
Proximal colorectal adenomas and non-polypoid lesions may play an important role in the development of interval CRCs.27 ,28 Our study is the first to demonstrate significant improvement in proximal ADR and non-polypoid lesion detection rate following quality improvement intervention. These results are in line with the primary goals of the training curriculum: emphasis on detection of subtle, non-polypoid lesions and visualisation of the proximal colon.
Endoscopist specialty and type of facility in which colonoscopy was performed have been associated with the risk of interval CRC.29 In our study, ADR improvement was observed across all endoscopist specialties, colonoscopy experience and types of screening facilities (see online supplementary table S3). In contrast, in previous studies on quality improvement through educational intervention, only gastroenterologists from academic institutions were included.13 ,19
The underlying hypothesis of our educational interventions was that the improvement in the detection of adenomas translates into reduced interval CRC rates. A recent large-scale study suggests that each 1% increase in ADR may result in a 3% decrease in the risk of interval cancer.3 We intend to follow our study cohort to investigate if improvement in ADR translates into reduced interval CRC rates.
Our study has some limitations. First, the cost-effectiveness of the training intervention is unknown. However, assuming that the relative risk of interval CRC among endoscopists with high and low ADR is comparable or greater than that observed for gastroenterologist and non-gastroenterologist endoscopists,29 ,30 it is likely that training to improve ADR will be as cost-effective as shifting screening colonoscopies from non-gastroenterologist endoscopists to gastroenterologist endoscopists.31 Second, total colonoscopy and withdrawal time were not routinely measured in our study. Thus, impact of the study interventions on procedure times is unknown. However, short term assessments, done by endoscopy nurses before and after intervention, suggest that observed improvement in ADR in the TCL group was most likely due to improved withdrawal technique rather than longer withdrawal time. This observation is in line with results of a previous study which showed that compared with withdrawal time, withdrawal technique might better differentiate between endoscopists with varying ADRs.32 Third, continuous, more frequent feedback of colonoscopy quality might be more effective than annual feedback. We decided to give feedback annually because of the sample size required to give a sufficiently precise estimate of ADR.33 Fourth, screening centre leaders were aware of being monitored under the study conditions. This might have affected their postintervention colonoscopy performance (the so-called Hawthorne effect34). Indeed, it is likely that some Hawthorne effect occurred in our study because in the late postintervention phase, colonoscopy performance of screening centre leaders declined slightly compared with the early postintervention phase. However, a Hawthorne effect had likely relatively small impact on our study results. Furthermore, this study included screening centre leaders with ADRs below 25%. It is uncertain if our results are applicable to leaders of endoscopy units outside screening setting and endoscopists with ADRs higher than 25%. Fifth, two screening centre leaders in each study group were lost to follow-up in the late postintervention phase, and thus the analyses for this period were not purely on an intention to treat basis. However, in the analyses we included all the data from screenees who underwent examination by endoscopists who performed screening examinations in the postintervention phase and did not withdraw their consent to participate in the trial, regardless of whether the training was complete or not (one screening centre leader did not participate in the pretraining and the post-training assessment but was included in the analyses). Moreover, in the late postintervention phase, we analysed all the centres that continued the screening programme, despite two leaders leaving their centres.
In summary, participation in a short, dedicated training intervention for screening centre leaders resulted in a greater improvement in ADR than audit and feedback of individual colonoscopy quality indicators. The observed quality improvement among leading colonoscopists and its dissemination on the entire screening centres support its widespread implementation.
This study was initiated and/or supported by representatives of the European Society of Gastrointestinal Endoscopy Quality Improvement Committee, the Polish Society of Gastroenterology Quality Section and the UK Joint Advisory Group on Gastrointestinal Endoscopy. The authors are grateful to all endoscopists and endoscopy nurses who participated in the study. The authors thank Milena Laskowska from the Maria Sklodowska-Curie Memorial Cancer Centre and Institute of Oncology, Warsaw, Poland, for her outstanding administrative support.
Review history and Supplementary material
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Files in this Data Supplement:
- Data supplement 1 - Online appendix
Contributors The study was conceived by MFK, EK and JR. All authors contributed to the development of the protocol. MFK, JA, RV, MB, ST-G and EJK designed the training intervention. MFK led the funding application and provided overall coordination of the project. MFK, JA, RV, MR, JP, EW and JR ran the training courses. MFK, EK and JR analysed the data. MFK wrote the first draft of the manuscript. All authors contributed to the interpretation of the data and the writing of the paper. MFK, EK and JR had full access to all of the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.
Funding This study was supported by the grant from the Polish Ministry of Science and Higher Education (IP2010016270), by the grant from the Foundation of Polish Science (TEAM/2012-9/5) financed by EU structural funds, Innovative Economy Operational Programme 2007–2013, and the Polish Ministry of Health. Michal F Kaminski received a stipend from the Polish Ministry of Science and Higher Education and the Foundation for Polish Science (TEAM/2012-9/5/styp6) during the study period.
Competing interests None.
Patient consent Obtained.
Ethics approval The Research Ethical Committee at the Maria Sklodowska-Curie Memorial Cancer Centre and Institute of Oncology.
Provenance and peer review Not commissioned; externally peer reviewed.
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