Colorectal Polyp Clinical Trial
Official title:
A Randomised Controlled Trial of the Prediction of Diminutive/Small Polyp Histology: a Comparison Between Didactic Training Versus Self-directed Computer Based Training
Bowel cancer is one of the most common cancers and the best method of diagnosing it is
through endoscopic examination of the bowel (colonoscopy). Pre-cursors of bowel cancer are
called polyps which can be detected and removed at the time of the colonoscopy. This reduces
the chance of developing bowel cancer. There are different types of polyp ranging from
completely harmless to those that may develop into cancer over time.
Advances in technology mean more polyps are being detected and it is possible to predict the
type of polyp. Therefore there is a new strategy in endoscopy whereby when a small polyp is
detected, a prediction of polyp type is made, the polyp removed and then discarded rather
than sending to the laboratory, thereby reducing costs to health services.
In the hands of experts, accuracies in predicting polyp type is similar to when the polyp is
removed and sent to the lab for analysis. Whilst experts can do this, non-experts cannot
reach these standards and there is a need for effective training.
The aim of the study is to compare the effectiveness of two training methods: Didactic
face-to-face training and computer-based self-learning on the ability of trainees at
predicting polyp type.
Colonoscopy is the gold standard for screening for bowel cancers and detection of pre-cursors
to colorectal cancer (polyps). Early detection of polyps, allows endoscopic removal and
therefore reduction in colorectal cancer. With improvements in technology endoscopists are
detecting more lesions within the bowel with the majority small/diminutive <5mm (80%),
however the clinical relevance of these lesions is minimal as the risk of advanced histology
or cancer is <1%. The current practice involves removing these lesions and sending for
histopathological assessment, incurring a significant risk to the patient, cost and is
time-consuming, with very little benefit. Novel imaging techniques including Narrow-band
imaging (NBI-Olympus, Japan), i-Scan Optical enhancement (OE-Pentax, Japan) and Blue-light
laser imaging (BLI- Fujifilm, Japan) can help endoscopists characterise these small lesions
between being neoplastic and non-neoplastic (hyperplastic). NBI involves the narrowing of
bandwidths of light using a light filter. The light at this end of the spectrum is absorbed
by haemoglobin (protein found within blood) therefore making blood vessels more pronounced.
During the process whereby a polyp develops and later becomes neoplastic, there is an
increase in blood vessels compared with normal tissue or hyperplastic polyps (benign),
therefore NBI can be used to detect such lesions. I-Scan OE is an alternative imaging
technique which enhances the pattern of the surface of polyps as well as the blood vessels,
by manipulating dark-light borders and red, blue and green components of light. Blue laser
imaging (BLI) is also new system for image-enhanced endoscopy using laser light. Blue laser
imaging utilizes two monochromatic lasers (410 and 450 nm) instead of xenon light. A 410 nm
laser visualizes vascular microarchitecture, similar to narrow band imaging, and a 450 nm
laser provides white light by excitation.
These novel technologies have been demonstrated to be superior over standard white light
endoscopy with NBI the most extensively investigated. A systematic analysis of 6 studies >500
polyps, resulted in a pooled sensitivity of 92%, spec 86%, accuracy of 89% at differentiating
neoplastic from non-neoplastic lesions when using NBI. Head to head studies of NBI versus
white light endoscopy (WLE) have shown NBI is better at differentiating between neoplastic
and non-neoplastic lesions. Similar results have been found with i-Scan, with performances
better than WLE and like NBI are similar to chromoendoscopy (a technique that involves
spraying dye over bowel mucosa which is time-consuming and costly). BLI is a newer imaging
platform, with the current evidence suggesting it is effective at differentiating polyps
(neoplastic versus non-neoplastic) with accuracies of 95.2%, and when comparing with white
light endoscopy the miss rate of adenoma was significantly lower with BLI (1.6% versus 10.0%
p=0.001).
In order to characterise between neoplastic and non-neoplastic lesions, endoscopic scoring
systems have been developed to assist endoscopists. Examples include NICE (NBI International
Colorectal Endoscopic).
Recently Iacucci et al have developed a simplified classification system (SIMPLE- Simplified
Identification Method for Polyp Labelling during the Endoscopy) for optical diagnosis of
small and diminutive adenomas, SSA/Ps and hyperplastic polyps using the newly introduced
OE-iSCAN system which achieved a high degree of diagnostic accuracy for small/diminutive
polyp diagnosis. Furthermore, they have showed that a training module on SIMPLE
classification resulted in an overall NPV of 91.3%. This user-friendly classification system
can be used by experienced and non-experienced gastroenterologists on multiple endoscopy
imaging platforms to differentiate neoplastic from non-neoplastic polyps. A classification
system developed by Bisschops R et al recently using BLI called BASIC (BLI Adenoma Serrated
International Classification). This takes into account the polyp surface, pit appearance and
vessels, which has shown to have a high concordance amongst experts.
In the hands of experts using NBI-NICE classification system accuracies of 98.9%, sensitivity
98%, specificity 100%, NPV 97.7% and PPV100% were demonstrated when diagnosis was made with
high confidence. Essential to the adopted use of these classifications is training for
endoscopists, both experienced and those in training. There is good evidence that there is a
short learning curve involved when using NBI. One study using a self-administered computer
based training module, community based gastroenterologists (non-expert) were able to reach
excellent NPV of >90% but fell short of other requirements (prediction of surveillance
intervals). Much like NBI, the learning curve at acquiring the skills in order to
differentiate between hyperplastic and adenomatous lesions using i-Scan has been
investigated. An early study by Neumann et al demonstrated a rapid learning curve with 4
endoscopists without previous experience with i-scan reached an accuracy of at least 85%
after reviewing 67-110 lesions (with individualised feedback) following a 1 hour teaching
session on pit pattern analysis.
There have attempts at identifying the most effective training tool and method at teaching
non-experts how to characterise lesions effectively. Studies have used still images of
lesions, however this is limited as it does not reflect real-life practice as it does not
allow views from different angles. It is thought videos simulate real-life practice as close
as possible. A study using videos has demonstrated trainees were able to achieve accuracies
of 90%.
More recently Rastogi's group sought to identify which training method was more effective in
prediction of diminutive polyp histology amongst trainees: didactic face to face training
versus computer-based self-learning. The participants were randomised to either receive
didactic training in the form of a classroom training session or self-learning via
computer-based material on characterisation of polyps using NBI. Trainees reviewed 40 videos
of diminutive polyps with the histology being revealed and explained. Both groups were given
a further 40 videos for testing. This study found those taught in the didactic group
characterised polyps with higher confidence, but the overall performance was similar in the
two groups. The accuracy and sensitivity were slightly better in the self-learning group
(93.9% vs 85.7% p 0.01 and 95.0% vs 86.9%; p0.03 respectively) in those polyps assessed with
high confidence. This study demonstrates that a computer-based training module can be as
effective in didactic training, perhaps a reflection on the amount of online self-learning
trainees are exposed to.
The investigators aim to recruit participants to receive either didactic face-to-face
training or self-directed computer based learning, whereby participants will be taught how to
characterise lesions using the NICE, BASIC and SIMPLE classification. The investigators aim
to recruit trainees, novice endoscopists and experienced endoscopists to compare the
different groups. Pre- and post-training assessments will be completed allowing us to examine
the impact of training, which will consist of 40-60 videos (equal proportion of NBI, iScan OE
and BLI) in the pre-training assessment and 40-60 videos (different set of videos but also
equal proportion of NBI, iScan OE and BLI) in the post-training assessment. A follow up
assessment will be completed at 6 months to assess the retention of skills and sustainability
of colonic polyp characterisation using the optical diagnosis techniques. An existing library
of NBI and OE-iScan videos will be used and further videos will be collected during routine
colonoscopies with patients consenting for images to be used for teaching purposes.
The investigators hypothesise that following the training module there will be an improvement
in performance between the pre-training and post-training assessments. The investigators also
hypothesise that there will be no difference between the didactic face-to-face group and the
self-training group.
This is an important study as better characterisation of small polyps may eventually lead to
a 'resect and discard' strategy in the future. This involves characterising small or
diminutive polyps (<10mm) as either non-neoplastic or neoplastic, resecting the lesion but
not sending for histopathological analysis, which has significant cost savings. In order to
do this training is essential. Whilst didactic training is attractive, it is costly and
resource heavy. The option of self-directed learning is an attractive one as it can be
delivered at times that suit the user, at their pace and can be delivered in greater volumes.
This study is unique as it is examining the impact of the training module on different groups
of participants (novice, training and experienced endoscopists), using multiple endoscopic
platforms(NBI, i-Scan OE and BLI) at a multicentre, international level. It will enable us to
assess whether the training module improves performance using different imaging modalities.
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