Updates in narrow‐band imaging for colorectal polyps: Narrow‐band imaging generations, detection, diagnosis, and artificial intelligence

Teramoto, Akira; Ventosa, Edgar; Ogino, Banri; Yasuda, Ichiro; Sano, Yasushi

doi:10.1111/den.14489

Cited by 5 publications

(7 citation statements)

References 117 publications

(185 reference statements)

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“…In contrast, our model can achieve good results with simple white-light colonoscopy alone. This outcome limits the convenience and widespread applicability of their models [ 9 ]. One of the contributions of our study is that our AI model works better for white light than NBI images.…”

Section: Discussionmentioning

confidence: 99%

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A colonial serrated polyp classification model using white-light ordinary endoscopy images with an artificial intelligence model and TensorFlow chart

Chen,

Wang,

et al. 2024

BMC Gastroenterol

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In this study, we implemented a combination of data augmentation and artificial intelligence (AI) model—Convolutional Neural Network (CNN)—to help physicians classify colonic polyps into traditional adenoma (TA), sessile serrated adenoma (SSA), and hyperplastic polyp (HP). We collected ordinary endoscopy images under both white and NBI lights. Under white light, we collected 257 images of HP, 423 images of SSA, and 60 images of TA. Under NBI light, were collected 238 images of HP, 284 images of SSA, and 71 images of TA. We implemented the CNN-based artificial intelligence model, Inception V4, to build a classification model for the types of colon polyps. Our final AI classification model with data augmentation process is constructed only with white light images. Our classification prediction accuracy of colon polyp type is 94%, and the discriminability of the model (area under the curve) was 98%. Thus, we can conclude that our model can help physicians distinguish between TA, SSA, and HPs and correctly identify precancerous lesions such as TA and SSA.

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Section: Discussionmentioning

confidence: 99%

“…For example, Azam et al [ 8 ] built an AI model with both wight-light and NBI images to improve the accuracy of their model. However, the NBI or other enhanced method has their weaknesses [ 9 ]. The efficiency of NBI is highly dependent on bowel preparation, and the image of NBI is darker than the white-light images.…”

Section: Introductionmentioning

confidence: 99%

A colonial serrated polyp classification model using white-light ordinary endoscopy images with an artificial intelligence model and TensorFlow chart

Chen,

Wang,

et al. 2024

BMC Gastroenterol

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“…First generation NBI was launched in 2006 as a part of two endoscopic systems, EVIS LUCERA SPECTRUM (in Japan and UK) and EXERA II (elsewhere) ( 31 ). Images generated by first-generation NBI were not ideal due to low brightness, and studies indicated that the adenoma detection rate (ADR) was comparable between NBI and WLE ( 32 , 33 ).…”

Section: Electronic Enhancing Techniques (Virtual Chromoendoscopy)mentioning

confidence: 99%

“…These models used a stronger xenon lamp and a new signal processor which worked by elimination of filter mechanism as well as reduction of image noise, thereby producing brighter sharp images. It also allowed an optical magnification of ×45 power with a simple press of a button ( 27 , 31 ). A recent meta-analysis of 11 RCTs involving 4,491 patients found that ADR for second-generation NBI was better compared to HD-WLE (OR: 1.28; 95% CI: 1.05–1.56; P=0.02) ( 34 ).…”

Section: Electronic Enhancing Techniques (Virtual Chromoendoscopy)mentioning

confidence: 99%

Image enhanced colonoscopy: updates and prospects—a review

Shahsavari¹,

Waqar²,

Chandrasekar³

2023

Transl Gastroenterol Hepatol

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Colonoscopy has been proven to be a successful approach in both identifying and preventing colorectal cancer. The incorporation of advanced imaging technologies, such as image-enhanced endoscopy (IEE), plays a vital role in real-time diagnosis. The advancements in endoscopic imaging technology have been continuous, from replacing fiber optics with charge-coupled devices to the introduction of chromoendoscopy in the 1970s. Recent technological advancements include “push-button” technologies like autofluorescence imaging (AFI), narrowed-spectrum endoscopy, and confocal laser endomicroscopy (CLE). Dye-based chromoendoscopy (DCE) is falling out of favor due to the longer time required for application and removal of the dye and the difficulty of identifying lesions in certain situations. Narrow band imaging (NBI) is a technology that filters the light used for illumination leading to improved contrast and better visibility of structures on the mucosal surface and has shown a consistently higher adenoma detection rate (ADR) compared to white light endoscopy. CLE has high sensitivity and specificity for polyp detection and characterization, and several classifications have been developed for accurate identification of normal, regenerative, and dysplastic epithelium. Other IEE technologies, such as blue laser imaging (BLI), linked-color imaging (LCI), i-SCAN, and AFI, have also shown promise in improving ADR and characterizing polyps. New technologies, such as Optivista, red dichromatic imaging (RDI), texture and color enhancement imaging (TXI), and computer-aided detection (CAD) using artificial intelligence (AI), are being developed to improve polyp detection and pathology prediction prior to widespread use in clinical practice.

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“…NBI is an optical digital imaging technique wherein two selected wavelengths (415 + −30 nm and 540 + −30 nm) enhance the structural aspects of the surface of the mucosa and existing blood vessels [ 12 ]. Numerous studies have shown that NBI is capable of accurate tissue characterization [ 8 , 13 , 14 , 15 ]. This strong evidence led to the development of the NBI International Colorectal Endoscopic (NICE) classification, which allows for an accurate differentiation between adenomatous and hyperplastic polyps in vivo by analyzing the color, surface pattern, and vascular pattern of DCPs with NBI [ 16 , 17 , 18 ].…”

Section: Introductionmentioning

confidence: 99%

The Utility of Narrow-Band Imaging International Colorectal Endoscopic Classification in Predicting the Histologies of Diminutive Colorectal Polyps Using I-Scan Optical Enhancement: A Prospective Study

Kang,

Lee,

Lee

2023

Diagnostics

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(1) Background: This study aimed to evaluate the accuracy of predicting the histology of diminutive colonic polyps (DCPs) (≤5 mm) using i-scan optical enhancement (OE) based on the narrow-band imaging international colorectal endoscopic (NICE) classification. The study compared the diagnostic accuracy between experts who were already familiar with the NICE classification and trainees who were not, both before and after receiving brief training on the NICE classification. (2) Method: This prospective, single-center clinical trial was conducted at the Dong-A University Hospital from March 2020 to August 2020 and involved two groups of participants. The first group comprised two experienced endoscopists who were proficient in using i-scan OE and had received formal training in optical diagnosis and dye-less chromoendoscopy (DLC) techniques. The second group consisted of three endoscopists in the process of training in internal medicine at the Dong-A University Hospital. Each endoscopist examined the polyps and evaluated them using the NICE classification through i-scan OE. The results were not among the participants. Trained endoscopists were divided into pre- and post-training groups. (3) Results: During the study, a total of 259 DCPs were assessed using i-scan OE by the two expert endoscopists. They made real-time histological predictions according to the NICE classification criteria. For the trainee group, before training, the area under the receiver operating characteristic curves (AUROCs) for predicting histopathological results using i-scan OE were 0.791, 0.775, and 0.818. However, after receiving training, the AUROCs improved to 0.935, 0.949, and 0.963, which were not significantly different from the results achieved by the expert endoscopists. (4) Conclusions: This study highlights the potential of i-scan OE, along with the NICE classification, in predicting the histopathological results of DCPs during colonoscopy. In addition, this study suggests that even an endoscopist without experience in DLC can effectively use i-scan OE to improve diagnostic performance with only brief training.

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Updates in narrow‐band imaging for colorectal polyps: Narrow‐band imaging generations, detection, diagnosis, and artificial intelligence

Cited by 5 publications

References 117 publications

A colonial serrated polyp classification model using white-light ordinary endoscopy images with an artificial intelligence model and TensorFlow chart

A colonial serrated polyp classification model using white-light ordinary endoscopy images with an artificial intelligence model and TensorFlow chart

Image enhanced colonoscopy: updates and prospects—a review

The Utility of Narrow-Band Imaging International Colorectal Endoscopic Classification in Predicting the Histologies of Diminutive Colorectal Polyps Using I-Scan Optical Enhancement: A Prospective Study

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