Colonic Polyps Clinical Trial
The aim of the study is to develop a computer program which is able to distinguish between
adenomatous and non- adenomatous polyps on the basis of optical features of the polyps.
Still images of polyps (< 10 mm of size) will be collected during routine colonoscopy
procedures. All polyps will be resected endoscopically so that histopathological diagnoses
(gold standard) can be notified.
In the validation phase of the study a computer program will be established which aims to
distinguish between adenomatous and non- adenomatous polyps on the basis of optical features
derived from still images. The program will operated using the the random forest learning
method. Afterwards, in the testing phase of the study, still images of 100 polyps (not used
in the validation phase) will be presented to the computer program. The establishment of a
well- functioning computer program is the primary aim of the study.
Adenomas are polyps of the colorectum that have the potential to develop into colon cancer
[1]. However, some adenomas never become malignant and if they do, progression from adenoma
into cancer usually takes a long time. As a result, screening colonoscopy programs were
established in order to detect and resect adenomas at an early stage [2]. After resection,
polyps should be sent to pathology in order to make a histological diagnosis. Not every
colorectal polyp has adenomatous histology. Approximately 40-50% of all polyps contain other
benign histology (e.g. hyperplastic or inflammatory polyps). These polyps do not bear the
risk of colon cancer.
The implementation of screening programs has led to increasing numbers of colonoscopies in
the last years [3]. This approach naturally implies higher amounts of detected polyps. The
removal of these polyps and consultation of a pathologist in order to make a diagnosis is
time consuming and expensive. An optical- based prediction of polyp histology (adenomatous
versus non- adenomatous) would enable endoscopists to save money and to inform patients
faster about examination results. The approach of predicting polyp histology on the basis of
optical features is called the "optical biopsy" method. The prediction is made by the
endoscopists during real-time colonoscopy. The aim of this strategy is to make an optical
diagnosis which enables users to resect polyps without sending the specimen to pathology.
Narrow Band Imaging (NBI) is a light-filter device which can be switched on during
colonoscopy. NBI is useful to better display vascular patterns of the colon mucosa. It has
been shown that the use of NBI can facilitate optical classification of colorectal polyps
[5]. A NBI- based classification schemes exists which can be used to assign polyps into
specific polyp categories (adenomatous versus non- adenomatous) [6].
Prior to the implementation of the optical classification approach for routine use in
endoscopy it is necessary to proof its feasibility and accuracy [7]. Otherwise the approach
would entail the risk of wrong diagnoses which could lead to wrong recommendations on
further diagnostic or therapeutic steps.
Until now, some clinical trials have shown good accuracy for the optical biopsy method [5].
However, there is growing evidence that optical biopsy does not yet meet demanded accuracy
thresholds [8]. The aim of our study is to create a computer program that is able to
distinguish between adenomatous and non-adenomatous polyps. Still images of colorectal
polyps including NBI- pictures of polyps will be used for machine learning (validation
phase). Afterwards a set of 100 still pictures will be used to test whether the computer
program is able to distinguish between adenomatous and non- adenomatous polyps (primary
endpoint). Statistical measures (accuracy, sensitivity, specificity) will be calculated.
;
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